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The rows in the periodic table are called periods and the columns in the periodic table are called groups.\u003C\/div\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Ch3\u003ELearning Objectives:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EAfter completing this module, you will be able to:\u003C\/div\u003E \r\n\u003Cdiv\u003E- Explain what groups and periods are.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Explain the criteria for placing elements in the periodic table.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Provide a suitable name for each group.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Arrange elements according to their atomic number.\u003C\/div\u003E","CONT_DESC_AR":"","BACKING_FILE":null,"FILE_UID":null,"SCORM_COURSE_ID":null,"CONT_SRC":null,"MOD_FILES":null,"FOLDER_NAME":null,"CONTTYPE_ID":"9","ANDROID_PKG":"com.umety.vr.hs200413","TOPIC_ID":"hs200413","IS_PUBLISH":"Y","IS_PUBLIC":"Y","CONT_PRICE":null,"PUBLIC_IMG":"thumb_HS200413.jpg","PUBLIC_BANNER_IMG":"HS200413.jpg","PUBLIC_VIDEO":"pvideo_hs200413.mp4","PUBLIC_VIDEO_URL":"https:\/\/youtu.be\/jnMKcnEqf5o","DIST":null,"SHOW_ON_HOME":"N","CONTROLLER_REQUIRED":"Y","DOMAIN":"3","CONCEPT":"0","STATUS":"A","EXPIRY_DAYS":null,"CREATED_ON":"2018-01-19 07:16:38","CREATED_BY":"0","UPDATED_ON":"0000-00-00 00:00:00","UPDATED_BY":"2","CONT_ORDER":"0","X_ROTATION":null,"Y_ROTATION":null,"Z_ROTATION":null,"BG_COLOR":"0x000000","X_POSITION":null,"Y_POSITION":null,"Z_POSITION":null,"TEMP_DESC":"Overview:\u0026lt;br\u0026gt;\u0026lt;br\u0026gt;The Periodic table is the systematic arrangement of 118 elements in the increasing order of their atomic number. The rows in the periodic table are called periods and the columns in the periodic table are called groups.\u0026lt;br\u0026gt;\u0026lt;br\u0026gt;Learning objectives\u0026lt;br\u0026gt;\u0026lt;br\u0026gt;\u0026lt;div\u0026gt;After completing this module, you will be able to:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Explain what groups and periods are.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Explain the criteria for placing elements in the periodic table.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Provide a suitable name for each group.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Arrange elements according to their atomic number.\u0026lt;\/div\u0026gt;","IS_ANALYTICS":"Y","VR_ENABLE":"Y","VR_SESSION_ENABLE":"Y","YOUTUBE_URL":null,"CONT_TYPE":"VR Module","CAT_NAME":"Today\u0027s periodic table","ADMSUBJECT_ID":"820","ADMCOURSE_ID":"217","DISPLAY_NAME":"Cambridge - AS \u0026 A level - Chemistry","DISPLAY_NAME_AR":"Cambridge - AS \u0026 A level - Chemistry","SUBJECT_NAME":"Chemistry","SUBJECT_NAME_AR":"Chemistry","SUBJECT_DESC":"Chemistry","SUBJECT_DESC_AR":"Chemistry","SUBJECT_IMG":"","SUBJECT_BANNER_IMG":null,"SUBJECT_PRICE":null,"IS_FEATURED":"N","COURSE_NAME":"AS \u0026 A level","COUNTRY_ID":"296","SHORT_NAME":"Cambridge (IGCSE)","DOMAIN_NAME":"STEM"},{"CONT_ID":"503","CATEGORY_ID":"1","CONT_TITLE":"Nucleic Acids","CONT_SLUG":"nucleic-acid","CONT_TITLE_AR":"","CONT_DESC":"\u003Ch3\u003EOverview:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003ENucleic acids are biomolecules present in living cells, especially DNA (deoxyribonucleic acid) or RNA (ribonucleic acid), whose molecules consist of many nucleotides linked in a long chain. Nucleic acid is made up of nucleotides. A nucleotide consists of a sugar, phosphate and nitrogenous base.\u003C\/div\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Ch3\u003ELearning Objectives:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EAfter completing this module, you will be able to:\u003C\/div\u003E \r\n\u003Cdiv\u003E- Explain what a nucleic acid is.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Describe the structure of a nucleotide.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Identify the different components of RNA and DNA.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Construct a nucleic acid.\u003C\/div\u003E","CONT_DESC_AR":"","BACKING_FILE":null,"FILE_UID":null,"SCORM_COURSE_ID":null,"CONT_SRC":null,"MOD_FILES":null,"FOLDER_NAME":null,"CONTTYPE_ID":"9","ANDROID_PKG":"com.umety.vr.hs200408","TOPIC_ID":"hs200408","IS_PUBLISH":"Y","IS_PUBLIC":"Y","CONT_PRICE":null,"PUBLIC_IMG":"thumb_HS200408.jpg","PUBLIC_BANNER_IMG":"HS200408.jpg","PUBLIC_VIDEO":"pvideo_hs200408.mp4","PUBLIC_VIDEO_URL":"https:\/\/youtu.be\/L5hwt0XTjzc","DIST":null,"SHOW_ON_HOME":"N","CONTROLLER_REQUIRED":"Y","DOMAIN":"3","CONCEPT":"0","STATUS":"A","EXPIRY_DAYS":null,"CREATED_ON":"2018-01-19 07:16:38","CREATED_BY":"0","UPDATED_ON":"0000-00-00 00:00:00","UPDATED_BY":"2","CONT_ORDER":"0","X_ROTATION":null,"Y_ROTATION":null,"Z_ROTATION":null,"BG_COLOR":"0x000000","X_POSITION":null,"Y_POSITION":null,"Z_POSITION":null,"TEMP_DESC":"Overview:\u0026lt;br\u0026gt;\u0026lt;br\u0026gt;Nucleic acids are biomolecules present in living cells, especially DNA (deoxyribonucleic acid) or RNA (ribonucleic acid), whose molecules consist of many nucleotides linked in a long chain. Nucleic acid is made up of nucleotides. A nucleotide consists of a sugar, phosphate and nitrogenous base.\u0026lt;br\u0026gt;\u0026lt;br\u0026gt;Learning objectives\u0026lt;br\u0026gt;\u0026lt;br\u0026gt;\u0026lt;div\u0026gt;After completing this module, you will be able to:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Explain what a nucleic acid is.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Describe the structure of a nucleotide.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Identify the different components of RNA and DNA.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Construct a nucleic acid.\u0026lt;\/div\u0026gt;","IS_ANALYTICS":"Y","VR_ENABLE":"Y","VR_SESSION_ENABLE":"Y","YOUTUBE_URL":null,"CONT_TYPE":"VR Module","CAT_NAME":"Nucleic acid","ADMSUBJECT_ID":"820","ADMCOURSE_ID":"217","DISPLAY_NAME":"Cambridge - AS \u0026 A level - Chemistry","DISPLAY_NAME_AR":"Cambridge - AS \u0026 A level - Chemistry","SUBJECT_NAME":"Chemistry","SUBJECT_NAME_AR":"Chemistry","SUBJECT_DESC":"Chemistry","SUBJECT_DESC_AR":"Chemistry","SUBJECT_IMG":"","SUBJECT_BANNER_IMG":null,"SUBJECT_PRICE":null,"IS_FEATURED":"N","COURSE_NAME":"AS \u0026 A level","COUNTRY_ID":"296","SHORT_NAME":"Cambridge (IGCSE)","DOMAIN_NAME":"STEM"},{"CONT_ID":"501","CATEGORY_ID":"1","CONT_TITLE":"Naming Hydrocarbons","CONT_SLUG":"naming-hydrocarbons","CONT_TITLE_AR":"","CONT_DESC":"\u003Ch3\u003EOverview:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EChemical compounds were named as per IUPAC nomenclature in order to avoid duplicate names. IUPAC nomenclature has one set of standardized rules. According to IUPAC system, the IUPAC name of an organic compound may consist of 5 parts that is: \u201cSecondary prefix + Primary prefix + Word root + Primary suffix + Secondary suffix\u201d.\u003C\/div\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Ch3\u003ELearning Objectives:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EAfter completing this module, you will be able to:\u003C\/div\u003E \r\n\u003Cdiv\u003E- Explain the different parts of the IUPAC name of an organic compound.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Name straight chain hydrocarbons according to the IUPAC guidelines.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Name branched hydrocarbons according to the IUPAC guidelines.\u003C\/div\u003E","CONT_DESC_AR":"","BACKING_FILE":null,"FILE_UID":null,"SCORM_COURSE_ID":null,"CONT_SRC":null,"MOD_FILES":null,"FOLDER_NAME":null,"CONTTYPE_ID":"9","ANDROID_PKG":"com.umety.vr.hs200402","TOPIC_ID":"hs200402","IS_PUBLISH":"Y","IS_PUBLIC":"Y","CONT_PRICE":null,"PUBLIC_IMG":"thumb_HS200402.jpg","PUBLIC_BANNER_IMG":"HS200402.jpg","PUBLIC_VIDEO":"pvideo_hs200402.mp4","PUBLIC_VIDEO_URL":"https:\/\/youtu.be\/7DPsmbPvpUw","DIST":null,"SHOW_ON_HOME":"N","CONTROLLER_REQUIRED":"Y","DOMAIN":"3","CONCEPT":"0","STATUS":"A","EXPIRY_DAYS":null,"CREATED_ON":"2018-01-19 07:16:38","CREATED_BY":"0","UPDATED_ON":"0000-00-00 00:00:00","UPDATED_BY":"2","CONT_ORDER":"0","X_ROTATION":null,"Y_ROTATION":null,"Z_ROTATION":null,"BG_COLOR":"0x000000","X_POSITION":null,"Y_POSITION":null,"Z_POSITION":null,"TEMP_DESC":"Overview:\u0026lt;br\u0026gt;\u0026lt;br\u0026gt;Chemical compounds were named as per IUPAC nomenclature in order to avoid duplicate names. IUPAC nomenclature has one set of standardized rules. According to IUPAC system, the IUPAC name of an organic compound may consist of 5 parts that is: \u201cSecondary prefix + Primary prefix + Word root + Primary suffix + Secondary suffix\u201d.\u0026lt;br\u0026gt;\u0026lt;br\u0026gt;Learning Objectives:\u0026lt;br\u0026gt;\u0026lt;br\u0026gt;\u0026lt;div\u0026gt;After completing this module, you will be able to:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Explain the different parts of the IUPAC name of an organic compound.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Name straight chain hydrocarbons according to the IUPAC guidelines.\u0026lt;\/div\u0026gt;- Name branched hydrocarbons according to the IUPAC guidelines.\u0026lt;br\u0026gt;","IS_ANALYTICS":"Y","VR_ENABLE":"Y","VR_SESSION_ENABLE":"Y","YOUTUBE_URL":null,"CONT_TYPE":"VR Module","CAT_NAME":"Naming hydrocarbons","ADMSUBJECT_ID":"820","ADMCOURSE_ID":"217","DISPLAY_NAME":"Cambridge - AS \u0026 A level - Chemistry","DISPLAY_NAME_AR":"Cambridge - AS \u0026 A level - Chemistry","SUBJECT_NAME":"Chemistry","SUBJECT_NAME_AR":"Chemistry","SUBJECT_DESC":"Chemistry","SUBJECT_DESC_AR":"Chemistry","SUBJECT_IMG":"","SUBJECT_BANNER_IMG":null,"SUBJECT_PRICE":null,"IS_FEATURED":"N","COURSE_NAME":"AS \u0026 A level","COUNTRY_ID":"296","SHORT_NAME":"Cambridge (IGCSE)","DOMAIN_NAME":"STEM"},{"CONT_ID":"494","CATEGORY_ID":"1","CONT_TITLE":"Like Dissolves Like","CONT_SLUG":"like-dissolves-like","CONT_TITLE_AR":"","CONT_DESC":"\u003Ch3\u003EOverview:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EPolar solutes tend to dissolve in polar solvents; nonpolar solutes tend to dissolve in nonpolar solvents. However, the dissolving nature also depends on the charge of the ions in the solution. Non-polar substances have Van der Waals attractions which are weak but present.\u003C\/div\u003E \r\n\u003Cdiv\u003E\u003Cbr\u003E\u003C\/div\u003E \r\n\u003Ch3\u003ELearning Objectives:\u003C\/h3\u003E \r\n\u003Cdiv\u003E\u003Cbr\u003E\u003C\/div\u003E \r\n\u003Cdiv\u003EAfter completing this module, you will be able to:\u003C\/div\u003E \r\n\u003Cdiv\u003E- Identify water as a polar solvent.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Identify ethanol as a polar solute.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Identify sodium chloride as an ionic solute.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Identify hexane as a nonpolar solvent.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Identify pentane as a nonpolar solute.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Describe the process of dissolving a polar solute in a polar solvent.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Describe the process of dissolving an ionic solute in a polar solvent.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Describe the process of dissolving a nonpolar solute in a nonpolar solvent.\u003C\/div\u003E","CONT_DESC_AR":"","BACKING_FILE":"hs200323.apk","FILE_UID":null,"SCORM_COURSE_ID":null,"CONT_SRC":null,"MOD_FILES":null,"FOLDER_NAME":null,"CONTTYPE_ID":"9","ANDROID_PKG":"com.umety.vr.hs200323","TOPIC_ID":"hs200323","IS_PUBLISH":"Y","IS_PUBLIC":"Y","CONT_PRICE":null,"PUBLIC_IMG":"thumb_HS200323.jpg","PUBLIC_BANNER_IMG":"HS200323.jpg","PUBLIC_VIDEO":"pvideo_hs200323.mp4","PUBLIC_VIDEO_URL":"https:\/\/youtu.be\/hLIZIr9usZ0","DIST":null,"SHOW_ON_HOME":"N","CONTROLLER_REQUIRED":"Y","DOMAIN":"3","CONCEPT":"0","STATUS":"A","EXPIRY_DAYS":null,"CREATED_ON":"2018-01-19 07:16:38","CREATED_BY":"0","UPDATED_ON":"0000-00-00 00:00:00","UPDATED_BY":"2","CONT_ORDER":"0","X_ROTATION":null,"Y_ROTATION":null,"Z_ROTATION":null,"BG_COLOR":"0x000000","X_POSITION":null,"Y_POSITION":null,"Z_POSITION":null,"TEMP_DESC":"Overview:\u0026lt;br\u0026gt;\u0026lt;br\u0026gt;Polar solutes tend to dissolve in polar solvents; nonpolar solutes tend to dissolve in nonpolar solvents. However, the dissolving nature also depends on the charge of the ions in the solution.\u0026amp;nbsp;\u0026lt;span style=\u0026quot;color: rgb(38, 50, 56); font-family: Roboto, sans-serif;\u0026quot;\u0026gt;Non-polar substances have Van der Waals attractions which are weak but present.\u0026lt;\/span\u0026gt;\u0026lt;br\u0026gt;\u0026lt;br\u0026gt;Learning objectives\u0026lt;br\u0026gt;\u0026lt;br\u0026gt;\u0026lt;div\u0026gt;After completing this module, you will be able to:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Identify water as a polar solvent.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Identify ethanol as a polar solute.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Identify sodium chloride as an ionic solute.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Identify hexane as a nonpolar solvent.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Identify pentane as a nonpolar solute.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Describe the process of dissolving a polar solute in a polar solvent.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Describe the process of dissolving an ionic solute in a polar solvent.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Describe the process of dissolving a nonpolar solute in a nonpolar solvent.\u0026lt;\/div\u0026gt;","IS_ANALYTICS":"Y","VR_ENABLE":"Y","VR_SESSION_ENABLE":"Y","YOUTUBE_URL":null,"CONT_TYPE":"VR Module","CAT_NAME":"Like dissolves like","ADMSUBJECT_ID":"820","ADMCOURSE_ID":"217","DISPLAY_NAME":"Cambridge - AS \u0026 A level - Chemistry","DISPLAY_NAME_AR":"Cambridge - AS \u0026 A level - Chemistry","SUBJECT_NAME":"Chemistry","SUBJECT_NAME_AR":"Chemistry","SUBJECT_DESC":"Chemistry","SUBJECT_DESC_AR":"Chemistry","SUBJECT_IMG":"","SUBJECT_BANNER_IMG":null,"SUBJECT_PRICE":null,"IS_FEATURED":"N","COURSE_NAME":"AS \u0026 A level","COUNTRY_ID":"296","SHORT_NAME":"Cambridge (IGCSE)","DOMAIN_NAME":"STEM"},{"CONT_ID":"492","CATEGORY_ID":"1","CONT_TITLE":"Covalent Compounds","CONT_SLUG":"covalent-compounds","CONT_TITLE_AR":"","CONT_DESC":"\u003Ch3\u003EOverview:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EA covalent compound is made when two or more nonmetal atoms bond by sharing valence electrons. Covalent compounds have low boiling point, melting point and thermal conductivity. They are insoluble in water and do not conduct electricity.\u003C\/div\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Ch3\u003ELearning objectives \u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EAfter completing this module, you will be able to: \u003C\/div\u003E \r\n\u003Cdiv\u003E- Identify what are covalent compounds. \u003C\/div\u003E \r\n\u003Cdiv\u003E- Observe the boiling points of the covalent compounds. \u003C\/div\u003E \r\n\u003Cdiv\u003E- Examine the solubility of the covalent compounds. \u003C\/div\u003E \r\n\u003Cdiv\u003E- Demonstrate the flame test for the covalent compounds. \u003C\/div\u003E \r\n\u003Cdiv\u003E- Demonstrate the thermal conductivity of the covalent compounds.\u003C\/div\u003E","CONT_DESC_AR":"","BACKING_FILE":"ms200312.apk","FILE_UID":null,"SCORM_COURSE_ID":null,"CONT_SRC":null,"MOD_FILES":null,"FOLDER_NAME":null,"CONTTYPE_ID":"9","ANDROID_PKG":"com.umety.vr.ms200312","TOPIC_ID":"ms200312","IS_PUBLISH":"Y","IS_PUBLIC":"Y","CONT_PRICE":null,"PUBLIC_IMG":"thumb_MS200312.jpg","PUBLIC_BANNER_IMG":"MS200312.jpg","PUBLIC_VIDEO":"pvideo_ms200312.mp4","PUBLIC_VIDEO_URL":"https:\/\/youtu.be\/63RXNIt5vA8","DIST":null,"SHOW_ON_HOME":"N","CONTROLLER_REQUIRED":"Y","DOMAIN":"3","CONCEPT":"0","STATUS":"A","EXPIRY_DAYS":null,"CREATED_ON":"2018-01-19 07:16:38","CREATED_BY":"0","UPDATED_ON":"0000-00-00 00:00:00","UPDATED_BY":"2","CONT_ORDER":"0","X_ROTATION":null,"Y_ROTATION":null,"Z_ROTATION":null,"BG_COLOR":"0x000000","X_POSITION":null,"Y_POSITION":null,"Z_POSITION":null,"TEMP_DESC":"Overview:\u0026lt;br\u0026gt;\u0026lt;br\u0026gt;A covalent compound is made when two or more nonmetal atoms bond by sharing valence electrons. Covalent compounds have low boiling point, melting point and thermal conductivity. They are insoluble in water and\u0026amp;nbsp; do not conduct electricity.\u0026lt;br\u0026gt;\u0026lt;br\u0026gt;Learning objectives\u0026lt;br\u0026gt;\u0026amp;nbsp;\u0026lt;br\u0026gt;After completing this module, you will be able to:\u0026lt;br\u0026gt;\u0026amp;nbsp;- Identify what are covalent compounds.\u0026lt;br\u0026gt;\u0026amp;nbsp;- Observe the boiling points of the covalent compounds.\u0026lt;br\u0026gt;\u0026amp;nbsp;- Examine the solubility of the covalent compounds.\u0026lt;br\u0026gt;\u0026amp;nbsp;- Demonstrate the flame test for the covalent compounds. \u0026lt;br\u0026gt;\u0026amp;nbsp;- Demonstrate the thermal conductivity of the covalent compounds.\u0026lt;br\u0026gt;","IS_ANALYTICS":"Y","VR_ENABLE":"Y","VR_SESSION_ENABLE":"Y","YOUTUBE_URL":null,"CONT_TYPE":"VR Module","CAT_NAME":"Covalent compounds","ADMSUBJECT_ID":"820","ADMCOURSE_ID":"217","DISPLAY_NAME":"Cambridge - AS \u0026 A level - Chemistry","DISPLAY_NAME_AR":"Cambridge - AS \u0026 A level - Chemistry","SUBJECT_NAME":"Chemistry","SUBJECT_NAME_AR":"Chemistry","SUBJECT_DESC":"Chemistry","SUBJECT_DESC_AR":"Chemistry","SUBJECT_IMG":"","SUBJECT_BANNER_IMG":null,"SUBJECT_PRICE":null,"IS_FEATURED":"N","COURSE_NAME":"AS \u0026 A level","COUNTRY_ID":"296","SHORT_NAME":"Cambridge (IGCSE)","DOMAIN_NAME":"STEM"},{"CONT_ID":"490","CATEGORY_ID":"1","CONT_TITLE":"Mass Number","CONT_SLUG":"mass-number","CONT_TITLE_AR":"","CONT_DESC":"\u003Ch3\u003EOverview:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EAn atom consists of three subatomic particles namely: electrons, protons and neutrons. The mass number of an atom is the sum of the number of protons and the number of neutrons in the nucleus.\u003C\/div\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Ch3\u003ELearning Objectives:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EAfter completing this module, you will be able to:\u003C\/div\u003E \r\n\u003Cdiv\u003E- Define mass number.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Identify the mass number of the first 20 elements in the periodic table.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Calculate the mass number of any element.\u003C\/div\u003E","CONT_DESC_AR":"","BACKING_FILE":null,"FILE_UID":null,"SCORM_COURSE_ID":null,"CONT_SRC":null,"MOD_FILES":null,"FOLDER_NAME":null,"CONTTYPE_ID":"9","ANDROID_PKG":"com.umety.vr.ms200296","TOPIC_ID":"ms200296","IS_PUBLISH":"Y","IS_PUBLIC":"Y","CONT_PRICE":null,"PUBLIC_IMG":"thumb_MS200296.jpg","PUBLIC_BANNER_IMG":"MS200296.jpg","PUBLIC_VIDEO":"pvideo_ms200296.mp4","PUBLIC_VIDEO_URL":"https:\/\/youtu.be\/BYE0r79sLXE","DIST":null,"SHOW_ON_HOME":"N","CONTROLLER_REQUIRED":"Y","DOMAIN":"3","CONCEPT":"0","STATUS":"A","EXPIRY_DAYS":null,"CREATED_ON":"2018-01-19 07:16:38","CREATED_BY":"0","UPDATED_ON":"0000-00-00 00:00:00","UPDATED_BY":"2","CONT_ORDER":"0","X_ROTATION":null,"Y_ROTATION":null,"Z_ROTATION":null,"BG_COLOR":"0x000000","X_POSITION":null,"Y_POSITION":null,"Z_POSITION":null,"TEMP_DESC":"Overview:\u0026lt;br\u0026gt;\u0026lt;br\u0026gt;An atom consists of three subatomic particles namely: electrons, protons and neutrons. The mass number of an atom is the sum of the number of protons and the number of neutrons in the nucleus.\u0026lt;br\u0026gt;\u0026lt;br\u0026gt;Learning objectives\u0026lt;br\u0026gt;\u0026lt;br\u0026gt;\u0026lt;div\u0026gt;After completing this module, you will be able to:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Define mass number.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Identify the mass number of the first 20 elements in the periodic table.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Calculate the mass number of any element.\u0026lt;\/div\u0026gt;","IS_ANALYTICS":"Y","VR_ENABLE":"Y","VR_SESSION_ENABLE":"Y","YOUTUBE_URL":null,"CONT_TYPE":"VR Module","CAT_NAME":"Mass number","ADMSUBJECT_ID":"820","ADMCOURSE_ID":"217","DISPLAY_NAME":"Cambridge - AS \u0026 A level - Chemistry","DISPLAY_NAME_AR":"Cambridge - AS \u0026 A level - Chemistry","SUBJECT_NAME":"Chemistry","SUBJECT_NAME_AR":"Chemistry","SUBJECT_DESC":"Chemistry","SUBJECT_DESC_AR":"Chemistry","SUBJECT_IMG":"","SUBJECT_BANNER_IMG":null,"SUBJECT_PRICE":null,"IS_FEATURED":"N","COURSE_NAME":"AS \u0026 A level","COUNTRY_ID":"296","SHORT_NAME":"Cambridge (IGCSE)","DOMAIN_NAME":"STEM"},{"CONT_ID":"489","CATEGORY_ID":"1","CONT_TITLE":"Atomic Number","CONT_SLUG":"atomic-number","CONT_TITLE_AR":"","CONT_DESC":"\u003Ch3\u003EOverview:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EAn element\u2019s atomic number is the number of protons present in the nucleus of that atom. When you look at an element in the periodic table, the number located in the upper left corner of the square is the atomic number of that element.\u003C\/div\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Ch3\u003ELearning Objectives:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EAfter completing this module, you will be able to: \u003C\/div\u003E \r\n\u003Cdiv\u003E- Define atomic number of an element. \u003C\/div\u003E \r\n\u003Cdiv\u003E- Locate an element\u0026#039;s atomic number in the periodic table. \u003C\/div\u003E \r\n\u003Cdiv\u003E- Calculate the number of electrons present in an atom or ion using its atomic number.\u003C\/div\u003E","CONT_DESC_AR":"","BACKING_FILE":null,"FILE_UID":null,"SCORM_COURSE_ID":null,"CONT_SRC":null,"MOD_FILES":null,"FOLDER_NAME":null,"CONTTYPE_ID":"9","ANDROID_PKG":"com.umety.vr.ms200295","TOPIC_ID":"ms200295","IS_PUBLISH":"Y","IS_PUBLIC":"Y","CONT_PRICE":null,"PUBLIC_IMG":"thumb_MS200295.jpg","PUBLIC_BANNER_IMG":"MS200295.jpg","PUBLIC_VIDEO":"pvideo_ms200295.mp4","PUBLIC_VIDEO_URL":"https:\/\/youtu.be\/eTGUbyjr8_g","DIST":null,"SHOW_ON_HOME":"N","CONTROLLER_REQUIRED":"Y","DOMAIN":"3","CONCEPT":"0","STATUS":"A","EXPIRY_DAYS":null,"CREATED_ON":"2018-01-19 07:16:38","CREATED_BY":"0","UPDATED_ON":"0000-00-00 00:00:00","UPDATED_BY":"2","CONT_ORDER":"0","X_ROTATION":null,"Y_ROTATION":null,"Z_ROTATION":null,"BG_COLOR":"0x000000","X_POSITION":null,"Y_POSITION":null,"Z_POSITION":null,"TEMP_DESC":"Overview:\u0026lt;br\u0026gt;\u0026lt;br\u0026gt;An element\u2019s atomic number is the number of protons present in the nucleus of that atom. When you look at an element in the periodic table, the number located in the upper left corner of the square is the atomic number of that element.\u0026lt;br\u0026gt;\u0026lt;br\u0026gt;Learning objectives\u0026lt;br\u0026gt;\u0026lt;br\u0026gt;After completing this module, you will be able to:\u0026lt;br\u0026gt;\u0026amp;nbsp;- Define atomic number of an element.\u0026lt;br\u0026gt;\u0026amp;nbsp;- Locate an element\u0026#039;s atomic number in the periodic table.\u0026lt;br\u0026gt;\u0026amp;nbsp;- Calculate the number of electrons present in an atom or ion using its atomic number.\u0026lt;br\u0026gt;","IS_ANALYTICS":"Y","VR_ENABLE":"Y","VR_SESSION_ENABLE":"Y","YOUTUBE_URL":null,"CONT_TYPE":"VR Module","CAT_NAME":"Atomic number","ADMSUBJECT_ID":"820","ADMCOURSE_ID":"217","DISPLAY_NAME":"Cambridge - AS \u0026 A level - Chemistry","DISPLAY_NAME_AR":"Cambridge - AS \u0026 A level - Chemistry","SUBJECT_NAME":"Chemistry","SUBJECT_NAME_AR":"Chemistry","SUBJECT_DESC":"Chemistry","SUBJECT_DESC_AR":"Chemistry","SUBJECT_IMG":"","SUBJECT_BANNER_IMG":null,"SUBJECT_PRICE":null,"IS_FEATURED":"N","COURSE_NAME":"AS \u0026 A level","COUNTRY_ID":"296","SHORT_NAME":"Cambridge (IGCSE)","DOMAIN_NAME":"STEM"},{"CONT_ID":"488","CATEGORY_ID":"1","CONT_TITLE":"Phase Change: Sublimation","CONT_SLUG":"phase-change-sublimation","CONT_TITLE_AR":"","CONT_DESC":"\u003Ch3\u003EOverview:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EThe process in which a solid directly changes its state to gas without undergoing the liquid phase is called sublimation. Examples of substances that undergo sublimation are camphor, naphthalene etc.\u003C\/div\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Ch3\u003ELearning Objectives:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EAfter completing this module, you will be able to:\u003C\/div\u003E \r\n\u003Cdiv\u003E- Define sublimation.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Explain the process of sublimation.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Identify substances that undergo sublimation.\u003C\/div\u003E","CONT_DESC_AR":"","BACKING_FILE":"ms200286.apk","FILE_UID":null,"SCORM_COURSE_ID":null,"CONT_SRC":null,"MOD_FILES":null,"FOLDER_NAME":null,"CONTTYPE_ID":"9","ANDROID_PKG":"com.umety.vr.ms200286","TOPIC_ID":"ms200286","IS_PUBLISH":"Y","IS_PUBLIC":"Y","CONT_PRICE":null,"PUBLIC_IMG":"thumb_MS200286.jpg","PUBLIC_BANNER_IMG":"MS200286.jpg","PUBLIC_VIDEO":"pvideo_ms200286.mp4","PUBLIC_VIDEO_URL":"https:\/\/youtu.be\/X1wc5E1F-ic","DIST":null,"SHOW_ON_HOME":"N","CONTROLLER_REQUIRED":"Y","DOMAIN":"3","CONCEPT":"0","STATUS":"A","EXPIRY_DAYS":null,"CREATED_ON":"2018-01-19 07:16:38","CREATED_BY":"0","UPDATED_ON":"0000-00-00 00:00:00","UPDATED_BY":"2","CONT_ORDER":"0","X_ROTATION":null,"Y_ROTATION":null,"Z_ROTATION":null,"BG_COLOR":"0x000000","X_POSITION":null,"Y_POSITION":null,"Z_POSITION":null,"TEMP_DESC":"Overview:\u0026lt;br\u0026gt;\u0026lt;br\u0026gt;The process in which a solid\u0026amp;nbsp; directly changes its state to gas without undergoing the liquid phase is called sublimation. Examples of substances that undergo sublimation are camphor, naphthalene etc.\u0026lt;br\u0026gt;\u0026lt;br\u0026gt;Learning objectives\u0026lt;br\u0026gt;\u0026lt;br\u0026gt;\u0026lt;div\u0026gt;After completing this module, you will be able to:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Define sublimation.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Explain the process of sublimation.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Identify substances that undergo sublimation.\u0026lt;\/div\u0026gt;","IS_ANALYTICS":"Y","VR_ENABLE":"Y","VR_SESSION_ENABLE":"Y","YOUTUBE_URL":null,"CONT_TYPE":"VR Module","CAT_NAME":"Phase change: Sublimation","ADMSUBJECT_ID":"820","ADMCOURSE_ID":"217","DISPLAY_NAME":"Cambridge - AS \u0026 A level - Chemistry","DISPLAY_NAME_AR":"Cambridge - AS \u0026 A level - Chemistry","SUBJECT_NAME":"Chemistry","SUBJECT_NAME_AR":"Chemistry","SUBJECT_DESC":"Chemistry","SUBJECT_DESC_AR":"Chemistry","SUBJECT_IMG":"","SUBJECT_BANNER_IMG":null,"SUBJECT_PRICE":null,"IS_FEATURED":"N","COURSE_NAME":"AS \u0026 A level","COUNTRY_ID":"296","SHORT_NAME":"Cambridge (IGCSE)","DOMAIN_NAME":"STEM"},{"CONT_ID":"487","CATEGORY_ID":"1","CONT_TITLE":"Phase Changes: Boiling, Evaporation and Condensation","CONT_SLUG":"phase-change-boiling-evaporation-and-condensation","CONT_TITLE_AR":"","CONT_DESC":"\u003Ch3\u003EOverview:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EThe change in state of liquid into gas is called vaporization. The process in which the vaporization occurs from the surface of a liquid is called evaporation. Whereas the process in which vaporization occurs within the surface of the liquid is called boiling. The change in state of gas into liquid is called condensation.\u003C\/div\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Ch3\u003ELearning Objectives:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EAfter completing this module, you will be able to: \u003C\/div\u003E \r\n\u003Cdiv\u003E- Define evaporation, boiling and condensation. \u003C\/div\u003E \r\n\u003Cdiv\u003E- Explain how liquid state and gaseous state of matter can be interchanged.\u003C\/div\u003E","CONT_DESC_AR":"","BACKING_FILE":"ms200285.apk","FILE_UID":null,"SCORM_COURSE_ID":null,"CONT_SRC":null,"MOD_FILES":null,"FOLDER_NAME":null,"CONTTYPE_ID":"9","ANDROID_PKG":"com.umety.vr.ms200285","TOPIC_ID":"ms200285","IS_PUBLISH":"Y","IS_PUBLIC":"Y","CONT_PRICE":null,"PUBLIC_IMG":"thumb_MS200285.jpg","PUBLIC_BANNER_IMG":"MS200285.jpg","PUBLIC_VIDEO":"pvideo_ms200285.mp4","PUBLIC_VIDEO_URL":"https:\/\/youtu.be\/B6ArYhP2pRY","DIST":null,"SHOW_ON_HOME":"N","CONTROLLER_REQUIRED":"Y","DOMAIN":"3","CONCEPT":"0","STATUS":"A","EXPIRY_DAYS":null,"CREATED_ON":"2018-01-19 07:16:38","CREATED_BY":"0","UPDATED_ON":"0000-00-00 00:00:00","UPDATED_BY":"2","CONT_ORDER":"0","X_ROTATION":null,"Y_ROTATION":null,"Z_ROTATION":null,"BG_COLOR":"0x000000","X_POSITION":null,"Y_POSITION":null,"Z_POSITION":null,"TEMP_DESC":"Overview:\u0026lt;br\u0026gt;\u0026lt;br\u0026gt;The change in state of liquid into gas is called vaporization. The process in which the vaporization occurs from the surface of\u0026amp;nbsp; a liquid is called evaporation. Whereas the process in which vaporization occurs within the surface of the liquid is called boiling. The change in state of gas into liquid is called condensation.\u0026lt;br\u0026gt;\u0026lt;br\u0026gt;Learning objectives\u0026lt;br\u0026gt;\u0026lt;br\u0026gt;After completing this module, you will be able to:\u0026lt;br\u0026gt;\u0026amp;nbsp;- Define evaporation, boiling and condensation.\u0026lt;br\u0026gt;\u0026amp;nbsp;- Explain how liquid state and gaseous state of matter can be interchanged.\u0026lt;br\u0026gt;","IS_ANALYTICS":"Y","VR_ENABLE":"Y","VR_SESSION_ENABLE":"Y","YOUTUBE_URL":null,"CONT_TYPE":"VR Module","CAT_NAME":"Phase change: Boiling, evaporation and condensation","ADMSUBJECT_ID":"820","ADMCOURSE_ID":"217","DISPLAY_NAME":"Cambridge - AS \u0026 A level - Chemistry","DISPLAY_NAME_AR":"Cambridge - AS \u0026 A level - Chemistry","SUBJECT_NAME":"Chemistry","SUBJECT_NAME_AR":"Chemistry","SUBJECT_DESC":"Chemistry","SUBJECT_DESC_AR":"Chemistry","SUBJECT_IMG":"","SUBJECT_BANNER_IMG":null,"SUBJECT_PRICE":null,"IS_FEATURED":"N","COURSE_NAME":"AS \u0026 A level","COUNTRY_ID":"296","SHORT_NAME":"Cambridge (IGCSE)","DOMAIN_NAME":"STEM"},{"CONT_ID":"484","CATEGORY_ID":"1","CONT_TITLE":"Effect of Surface Area on Reaction Rate","CONT_SLUG":"effect-of-surface-area-on-reaction-rate","CONT_TITLE_AR":"","CONT_DESC":"\u003Ch3\u003EOverview:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EWhen a solid lump is subdivided into fine powder, the surface area increases and more particles are exposed for collisions. This results in an increased frequency of collisions and therefore a faster rate of reaction.\u003C\/div\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Ch3\u003ELearning Objectives:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EAfter completing this module, you will be able to :\u003C\/div\u003E \r\n\u003Cdiv\u003E- Identify the effect of surface area of solid reactant on rate of reaction.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Illustrate graphically the effect of surface area of solid reactant on rate of reaction.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Explain the effect of increasing surface area on reaction rate using collision theory.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Apply this concept in practical problems.\u003C\/div\u003E","CONT_DESC_AR":"","BACKING_FILE":null,"FILE_UID":null,"SCORM_COURSE_ID":null,"CONT_SRC":null,"MOD_FILES":null,"FOLDER_NAME":null,"CONTTYPE_ID":"9","ANDROID_PKG":"com.umety.vr.hs200277","TOPIC_ID":"hs200277","IS_PUBLISH":"Y","IS_PUBLIC":"Y","CONT_PRICE":null,"PUBLIC_IMG":"thumb_HS200277.jpg","PUBLIC_BANNER_IMG":"HS200277.jpg","PUBLIC_VIDEO":"pvideo_hs200277.mp4","PUBLIC_VIDEO_URL":"https:\/\/youtu.be\/m8t8U2eJnj0","DIST":null,"SHOW_ON_HOME":"N","CONTROLLER_REQUIRED":"Y","DOMAIN":"3","CONCEPT":"0","STATUS":"A","EXPIRY_DAYS":null,"CREATED_ON":"2018-01-19 07:16:38","CREATED_BY":"0","UPDATED_ON":"0000-00-00 00:00:00","UPDATED_BY":"2","CONT_ORDER":"0","X_ROTATION":null,"Y_ROTATION":null,"Z_ROTATION":null,"BG_COLOR":"0x000000","X_POSITION":null,"Y_POSITION":null,"Z_POSITION":null,"TEMP_DESC":"Overview:\u0026lt;br\u0026gt;\u0026lt;br\u0026gt;When a solid lump is subdivided into fine powder, the surface area increases and more particles are exposed for collisions. This results in an increased frequency of collisions and therefore a faster rate of reaction.\u0026lt;br\u0026gt;\u0026lt;br\u0026gt;Learning objectives\u0026lt;br\u0026gt;\u0026lt;br\u0026gt;After completing this module, you will be able to :\u0026lt;br\u0026gt;- Identify the effect of surface area of solid reactant on rate of reaction.\u0026lt;br\u0026gt;- Illustrate graphically the effect of surface area of solid reactant on rate of reaction.\u0026lt;br\u0026gt;- Explain the effect of increasing surface area on reaction rate using collision theory.\u0026lt;br\u0026gt;- Apply this concept in practical problems.\u0026lt;br\u0026gt;\u0026lt;br\u0026gt;","IS_ANALYTICS":"Y","VR_ENABLE":"Y","VR_SESSION_ENABLE":"Y","YOUTUBE_URL":null,"CONT_TYPE":"VR Module","CAT_NAME":"Effect of surface area on reaction rate","ADMSUBJECT_ID":"820","ADMCOURSE_ID":"217","DISPLAY_NAME":"Cambridge - AS \u0026 A level - Chemistry","DISPLAY_NAME_AR":"Cambridge - AS \u0026 A level - Chemistry","SUBJECT_NAME":"Chemistry","SUBJECT_NAME_AR":"Chemistry","SUBJECT_DESC":"Chemistry","SUBJECT_DESC_AR":"Chemistry","SUBJECT_IMG":"","SUBJECT_BANNER_IMG":null,"SUBJECT_PRICE":null,"IS_FEATURED":"N","COURSE_NAME":"AS \u0026 A level","COUNTRY_ID":"296","SHORT_NAME":"Cambridge (IGCSE)","DOMAIN_NAME":"STEM"},{"CONT_ID":"398","CATEGORY_ID":"1","CONT_TITLE":"Bases","CONT_SLUG":"bases","CONT_TITLE_AR":"Bases","CONT_DESC":"\u003Ch3\u003EOverview:\u003C\/h3\u003E \r\n\u003Cdiv\u003E\u003Cbr\u003E\u003C\/div\u003E \r\n\u003Cdiv\u003EA base is a compound that gives hydroxide ion on ionization. Bases are usually bitter in taste.\u003C\/div\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Ch3\u003ELearning Objectives:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EAfter completing this module, you will be able to:\u003C\/div\u003E \r\n\u003Cdiv\u003E- Define bases.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Identify the properties of bases.\u003C\/div\u003E","CONT_DESC_AR":"A base is a compound that gives hydroxide ion on ionisation. Bases are usually bitter in taste.\u003C\/br\u003E\u003C\/br\u003E\r\n\u003Cstrong\u003ELearning Objectives\u003C\/strong\u003E\u003C\/br\u003E\u003C\/br\u003E\r\nIn this simulation, you will be able to:\u003C\/br\u003E\r\n\u2022 define bases\u003C\/br\u003E\r\n\u2022 identify the properties of bases","BACKING_FILE":"hs200060.apk","FILE_UID":null,"SCORM_COURSE_ID":null,"CONT_SRC":"","MOD_FILES":null,"FOLDER_NAME":null,"CONTTYPE_ID":"9","ANDROID_PKG":"com.umety.vr.hs200060","TOPIC_ID":"hs200060","IS_PUBLISH":"Y","IS_PUBLIC":"Y","CONT_PRICE":null,"PUBLIC_IMG":"thumb_HS200060.jpg","PUBLIC_BANNER_IMG":"HS200060.jpg","PUBLIC_VIDEO":"pvideo_hs200060.mp4","PUBLIC_VIDEO_URL":"https:\/\/youtu.be\/44_TMLTKv5A","DIST":null,"SHOW_ON_HOME":"N","CONTROLLER_REQUIRED":"Y","DOMAIN":"3","CONCEPT":"0","STATUS":"A","EXPIRY_DAYS":null,"CREATED_ON":"2018-01-19 07:16:38","CREATED_BY":"1","UPDATED_ON":"0000-00-00 00:00:00","UPDATED_BY":"2","CONT_ORDER":"0","X_ROTATION":null,"Y_ROTATION":null,"Z_ROTATION":null,"BG_COLOR":"0x000000","X_POSITION":null,"Y_POSITION":null,"Z_POSITION":null,"TEMP_DESC":"\u003Ch3\u003EOverview:\u003C\/h3\u003E\u003Cbr\u003E\u003Cdiv\u003EA base is a compound that gives hydroxide ion on ionization. Bases are usually bitter in taste.\u003C\/div\u003E\u003Cdiv\u003E\u003Cbr\u003E\u003C\/div\u003E\u003Ch3\u003ELearning Objectives:\u003C\/h3\u003E\u003Cdiv\u003E\u003Cbr\u003E\u003C\/div\u003E\u003Cdiv\u003E\u003Cdiv\u003EAfter completing this module, you will be able to:\u003C\/div\u003E\u003Cdiv\u003E- Define bases.\u003C\/div\u003E\u003Cdiv\u003E- Identify the properties of bases.\u003C\/div\u003E\u003C\/div\u003E","IS_ANALYTICS":"Y","VR_ENABLE":"Y","VR_SESSION_ENABLE":"Y","YOUTUBE_URL":null,"CONT_TYPE":"VR Module","CAT_NAME":"Bases","ADMSUBJECT_ID":"820","ADMCOURSE_ID":"217","DISPLAY_NAME":"Cambridge - AS \u0026 A level - Chemistry","DISPLAY_NAME_AR":"Cambridge - AS \u0026 A level - Chemistry","SUBJECT_NAME":"Chemistry","SUBJECT_NAME_AR":"Chemistry","SUBJECT_DESC":"Chemistry","SUBJECT_DESC_AR":"Chemistry","SUBJECT_IMG":"","SUBJECT_BANNER_IMG":null,"SUBJECT_PRICE":null,"IS_FEATURED":"N","COURSE_NAME":"AS \u0026 A level","COUNTRY_ID":"296","SHORT_NAME":"Cambridge (IGCSE)","DOMAIN_NAME":"STEM"},{"CONT_ID":"372","CATEGORY_ID":"1","CONT_TITLE":"Application of VSEPR Theory","CONT_SLUG":"application-of-vsepr-theory","CONT_TITLE_AR":"Application of VSEPR Theory","CONT_DESC":"\u003Ch3\u003EOverview:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EValence shell electron pair repulsion (VSEPR) theory is used in chemistry to predict the three-dimensional shapes of molecules from the number of electron pairs surrounding their central atoms. Molecules can have linear, trigonal planar, bent, tetrahedral, trigonal bipyramidal, seesaw, T-shaped, octahedral, square pyramidal or pentagonal bipyramidal geometries.\u003C\/div\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Ch3\u003ELearning Objectives:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EAfter completing this module, you will be able to:\u003C\/div\u003E \r\n\u003Cdiv\u003E- Construct molecules having linear, trigonal planar, bent, tetrahedral, trigonal bipyramidal, seesaw, T-shaped, octahedral, square pyramidal and pentagonal bipyramidal geometries.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Apply VSEPR theory to predict the three-dimensional shapes of molecules.\u003C\/div\u003E","CONT_DESC_AR":"Valence shell electron pair repulsion (VSEPR)\u0026amp;nbsp;theory\u0026amp;nbsp;is used in chemistry to predict the three-dimensional shapes of molecules from the number of electron pairs surrounding their central atoms. Molecules can have linear, trigonal planar, bent, tetrahedral, trigonal bipyramidal, seesaw, T-shaped, octahedral, square pyramidal or pentagonal bipyramidal geometries.\u0026amp;nbsp;\u0026lt;br \/\u0026gt;\n\u0026lt;br \/\u0026gt;\n\u0026lt;strong\u0026gt;Learning Objectives\u0026lt;\/strong\u0026gt;\u0026lt;br \/\u0026gt;\n\u0026lt;br \/\u0026gt;\nIn this simulation you will be able to:\u0026lt;br \/\u0026gt;\n- construct molecules having linear, trigonal planar, bent, tetrahedral, trigonal bipyramidal, seesaw, T-shaped, octahedral, square pyramidal and pentagonal bipyramidal geometries\u0026amp;nbsp;\u0026lt;br \/\u0026gt;\n- apply VSEPR theory to predict the three-dimensional shapes of molecules","BACKING_FILE":null,"FILE_UID":null,"SCORM_COURSE_ID":null,"CONT_SRC":"","MOD_FILES":null,"FOLDER_NAME":null,"CONTTYPE_ID":"9","ANDROID_PKG":"com.umety.vr.ss200035","TOPIC_ID":"ss200035","IS_PUBLISH":"Y","IS_PUBLIC":"Y","CONT_PRICE":null,"PUBLIC_IMG":"thumb_SS200035.jpg","PUBLIC_BANNER_IMG":"SS200035.jpg","PUBLIC_VIDEO":"pvideo_ss200035.mp4","PUBLIC_VIDEO_URL":"https:\/\/youtu.be\/gR_7S2Lk39g","DIST":null,"SHOW_ON_HOME":"N","CONTROLLER_REQUIRED":"Y","DOMAIN":"3","CONCEPT":"0","STATUS":"A","EXPIRY_DAYS":null,"CREATED_ON":"2018-01-19 07:16:38","CREATED_BY":"1","UPDATED_ON":"0000-00-00 00:00:00","UPDATED_BY":"2","CONT_ORDER":"0","X_ROTATION":null,"Y_ROTATION":null,"Z_ROTATION":null,"BG_COLOR":"0x000000","X_POSITION":null,"Y_POSITION":null,"Z_POSITION":null,"TEMP_DESC":"\u0026lt;div\u0026gt;Overview:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;Valence shell electron pair repulsion (VSEPR) theory is used in chemistry to predict the three-dimensional shapes of molecules from the number of electron pairs surrounding their central atoms. Molecules can have linear, trigonal planar, bent, tetrahedral, trigonal bipyramidal, seesaw, T-shaped, octahedral, square pyramidal or pentagonal bipyramidal geometries.\u0026amp;nbsp;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;Learning Objectives:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;div\u0026gt;After completing this module, you will be able to:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Construct molecules having linear, trigonal planar, bent, tetrahedral, trigonal bipyramidal, seesaw, T-shaped, octahedral, square pyramidal and pentagonal bipyramidal geometries.\u0026amp;nbsp;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Apply VSEPR theory to predict the three-dimensional shapes of molecules.\u0026lt;\/div\u0026gt;\u0026lt;\/div\u0026gt;","IS_ANALYTICS":"Y","VR_ENABLE":"Y","VR_SESSION_ENABLE":"Y","YOUTUBE_URL":null,"CONT_TYPE":"VR Module","CAT_NAME":"Application of VSEPR theory","ADMSUBJECT_ID":"820","ADMCOURSE_ID":"217","DISPLAY_NAME":"Cambridge - AS \u0026 A level - Chemistry","DISPLAY_NAME_AR":"Cambridge - AS \u0026 A level - Chemistry","SUBJECT_NAME":"Chemistry","SUBJECT_NAME_AR":"Chemistry","SUBJECT_DESC":"Chemistry","SUBJECT_DESC_AR":"Chemistry","SUBJECT_IMG":"","SUBJECT_BANNER_IMG":null,"SUBJECT_PRICE":null,"IS_FEATURED":"N","COURSE_NAME":"AS \u0026 A level","COUNTRY_ID":"296","SHORT_NAME":"Cambridge (IGCSE)","DOMAIN_NAME":"STEM"},{"CONT_ID":"371","CATEGORY_ID":"1","CONT_TITLE":"VSEPR Theory","CONT_SLUG":"vsepr-theory","CONT_TITLE_AR":"VSEPR Theory","CONT_DESC":"\u003Ch3\u003EOverview:\u003C\/h3\u003E \u003Cdiv\u003E  \u003Cbr\u003E \u003C\/div\u003E \u003Cdiv\u003EValence shell electron pair repulsion (VSEPR) theory suggests that the electron pairs surrounding the central atom repel each other and tend to occupy such positions around the central atom that minimize this repulsion. According to this theory, the geometry of a molecule depends upon the total number of electron pairs present around the central atom.\u003C\/div\u003E \u003Cdiv\u003E  \u003Cbr\u003E \u003C\/div\u003E \u003Ch3\u003ELearning Objectives:\u003C\/h3\u003E \u003Cdiv\u003E  \u003Cbr\u003E \u003C\/div\u003E \u003Cdiv\u003EAfter completing this module, you will be able to:\u003C\/div\u003E \u003Cdiv\u003E- Explain valence shell electron pair repulsion (VSEPR) theory.\u003C\/div\u003E \u003Cdiv\u003E- Predict the geometry of individual molecules from the number of electron pairs surrounding their central atoms.\u003C\/div\u003E","CONT_DESC_AR":"According to valence shell electron pair repulsion (VSEPR) theory, the valence electron pairs surrounding an atom mutually repel each other. They adopt an arrangement that minimizes this repulsion, thus determining its molecular geometry. This means that bonding and non-bonding electrons will repel each other as far away as geometrically possible. The number of atoms bonded to a central atom combined with the number of pairs of its non-bonding valence electrons is called its steric number.\u0026lt;br \/\u0026gt;\n\u0026lt;br \/\u0026gt;\n\u0026lt;strong\u0026gt;Learning Objectives\u0026lt;\/strong\u0026gt;\u0026lt;br \/\u0026gt;\n\u0026lt;br \/\u0026gt;\nIn this simulation, you will be able to:\u0026lt;br \/\u0026gt;\n\u0026amp;bull; explain Valence shell electron pair repulsion (VSEPR) theory\u0026lt;br \/\u0026gt;\n\u0026amp;bull; predict the geometry of individual molecules from the number of electron pairs surrounding their central atoms","BACKING_FILE":null,"FILE_UID":null,"SCORM_COURSE_ID":null,"CONT_SRC":"","MOD_FILES":null,"FOLDER_NAME":null,"CONTTYPE_ID":"9","ANDROID_PKG":"com.umety.vr.ss200034","TOPIC_ID":"ss200034","IS_PUBLISH":"Y","IS_PUBLIC":"Y","CONT_PRICE":null,"PUBLIC_IMG":"thumb_SS200034.jpg","PUBLIC_BANNER_IMG":"SS200034.jpg","PUBLIC_VIDEO":"pvideo_ss200034.mp4","PUBLIC_VIDEO_URL":"https:\/\/youtu.be\/RVz4Vp1j4nQ","DIST":null,"SHOW_ON_HOME":"N","CONTROLLER_REQUIRED":"Y","DOMAIN":"3","CONCEPT":"0","STATUS":"A","EXPIRY_DAYS":null,"CREATED_ON":"2018-01-19 07:16:38","CREATED_BY":"1","UPDATED_ON":"0000-00-00 00:00:00","UPDATED_BY":"2","CONT_ORDER":"0","X_ROTATION":null,"Y_ROTATION":null,"Z_ROTATION":null,"BG_COLOR":"0x000000","X_POSITION":null,"Y_POSITION":null,"Z_POSITION":null,"TEMP_DESC":"\u0026lt;div\u0026gt;Overview:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;Valence shell electron pair repulsion (VSEPR) theory suggests that the electron pairs surrounding the central atom repel each other and tend to occupy such positions around the central atom that minimize this repulsion. According to this theory, the geometry of a molecule depends upon the total number of electron pairs present around the central atom.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;span style=\u0026quot;font-weight: bold;\u0026quot;\u0026gt;Learning Objectives:\u0026lt;\/span\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;div\u0026gt;After completing this module, you will be able to:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Explain valence shell electron pair repulsion (VSEPR) theory.\u0026amp;nbsp;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Predict the geometry of individual molecules from the number of electron pairs surrounding their central atoms.\u0026lt;\/div\u0026gt;\u0026lt;\/div\u0026gt;","IS_ANALYTICS":"Y","VR_ENABLE":"Y","VR_SESSION_ENABLE":"Y","YOUTUBE_URL":null,"CONT_TYPE":"VR Module","CAT_NAME":"VSEPR Theory","ADMSUBJECT_ID":"820","ADMCOURSE_ID":"217","DISPLAY_NAME":"Cambridge - AS \u0026 A level - Chemistry","DISPLAY_NAME_AR":"Cambridge - AS \u0026 A level - Chemistry","SUBJECT_NAME":"Chemistry","SUBJECT_NAME_AR":"Chemistry","SUBJECT_DESC":"Chemistry","SUBJECT_DESC_AR":"Chemistry","SUBJECT_IMG":"","SUBJECT_BANNER_IMG":null,"SUBJECT_PRICE":null,"IS_FEATURED":"N","COURSE_NAME":"AS \u0026 A level","COUNTRY_ID":"296","SHORT_NAME":"Cambridge (IGCSE)","DOMAIN_NAME":"STEM"},{"CONT_ID":"370","CATEGORY_ID":"1","CONT_TITLE":"pH of a Solution","CONT_SLUG":"ph-of-a-solution","CONT_TITLE_AR":"pH of a Solution","CONT_DESC":"\u003Ch3\u003EOverview:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EAn aqueous solution can be acidic, basic or neutral based, on the pH of the solution. A neutral solution like pure water has an equal number of hydronium ions and hydroxide ions, while an acidic solution has more hydronium ions than hydroxide ions, and basic solutions have more hydroxide ions than hydronium ions.\u003C\/div\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Ch3\u003ELearning Objectives:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EAfter completing this module, you will be able to:\u003C\/div\u003E \r\n\u003Cdiv\u003E- Measure the pH of a strong acid with the help of a pH meter.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Measure the pH of a strong base with the help of a pH meter.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Identify whether a solution is acidic or basic.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Calculate the pH of a strong acid.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Calculate the pH of a strong base.\u003C\/div\u003E","CONT_DESC_AR":"An aqueous solution can be acidic, basic or neutral based on the pH of the solution. A neutral solution like pure water has an equal number of hydronium ions and hydroxide ions, while an acidic solution has more hydronium ions than hydroxide ions, and basic solutions have more hydroxide ions than hydronium ions.\u0026lt;br \/\u0026gt;\n\u0026lt;br \/\u0026gt;\n\u0026lt;strong\u0026gt;Learning Objectives\u0026lt;\/strong\u0026gt;\u0026lt;br \/\u0026gt;\n\u0026lt;br \/\u0026gt;\nIn this simulation , you will be able to:\u0026lt;br \/\u0026gt;\n\u0026amp;bull; identify whether a solution is acidic, basic or neutral\u0026lt;br \/\u0026gt;\n\u0026amp;bull;\u0026amp;nbsp;calculate the pH of an aqueous solution\u0026lt;br \/\u0026gt;\n\u0026amp;bull;\u0026amp;nbsp;calculate\u0026amp;nbsp;the hydronium ion and hydroxide ion concentrations of an aqueous\u0026amp;nbsp;solution","BACKING_FILE":"ss200071.apk","FILE_UID":null,"SCORM_COURSE_ID":null,"CONT_SRC":"","MOD_FILES":null,"FOLDER_NAME":null,"CONTTYPE_ID":"9","ANDROID_PKG":"com.umety.vr.ss200071","TOPIC_ID":"ss200071","IS_PUBLISH":"Y","IS_PUBLIC":"Y","CONT_PRICE":null,"PUBLIC_IMG":"thumb_SS200071.jpg","PUBLIC_BANNER_IMG":"SS200071.jpg","PUBLIC_VIDEO":"pvideo_ss200071.mp4","PUBLIC_VIDEO_URL":"https:\/\/youtu.be\/KOn_tFIwyd4","DIST":null,"SHOW_ON_HOME":"N","CONTROLLER_REQUIRED":"Y","DOMAIN":"3","CONCEPT":"0","STATUS":"A","EXPIRY_DAYS":null,"CREATED_ON":"2018-01-19 07:16:38","CREATED_BY":"1","UPDATED_ON":"0000-00-00 00:00:00","UPDATED_BY":"2","CONT_ORDER":"0","X_ROTATION":null,"Y_ROTATION":null,"Z_ROTATION":null,"BG_COLOR":"0x000000","X_POSITION":null,"Y_POSITION":null,"Z_POSITION":null,"TEMP_DESC":"\u0026lt;div\u0026gt;Overview:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;An aqueous solution can be acidic, basic or neutral based, on the pH of the solution. A neutral solution like pure water has an equal number of hydronium ions and hydroxide ions, while an acidic solution has more hydronium ions than hydroxide ions, and basic solutions have more hydroxide ions than hydronium ions.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;Learning Objectives:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;span style=\u0026quot;font-size: 13px;\u0026quot;\u0026gt;After completing this module, you will be able to:\u0026lt;\/span\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;span style=\u0026quot;font-size: 13px;\u0026quot;\u0026gt;- Measure the pH of a strong acid with the help of a pH meter.\u0026lt;\/span\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;span style=\u0026quot;font-size: 13px;\u0026quot;\u0026gt;- Measure the pH of a strong base with the help of a pH meter.\u0026lt;\/span\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;span style=\u0026quot;font-size: 13px;\u0026quot;\u0026gt;- Identify whether a solution is acidic or basic.\u0026lt;\/span\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;span style=\u0026quot;font-size: 13px;\u0026quot;\u0026gt;- Calculate the pH of a strong acid.\u0026lt;\/span\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;span style=\u0026quot;font-size: 13px;\u0026quot;\u0026gt;- Calculate the pH of a strong base\u0026lt;\/span\u0026gt;.\u0026lt;\/div\u0026gt;\u0026lt;\/div\u0026gt;","IS_ANALYTICS":"Y","VR_ENABLE":"Y","VR_SESSION_ENABLE":"Y","YOUTUBE_URL":null,"CONT_TYPE":"VR Module","CAT_NAME":"pH of a solution","ADMSUBJECT_ID":"820","ADMCOURSE_ID":"217","DISPLAY_NAME":"Cambridge - AS \u0026 A level - Chemistry","DISPLAY_NAME_AR":"Cambridge - AS \u0026 A level - Chemistry","SUBJECT_NAME":"Chemistry","SUBJECT_NAME_AR":"Chemistry","SUBJECT_DESC":"Chemistry","SUBJECT_DESC_AR":"Chemistry","SUBJECT_IMG":"","SUBJECT_BANNER_IMG":null,"SUBJECT_PRICE":null,"IS_FEATURED":"N","COURSE_NAME":"AS \u0026 A level","COUNTRY_ID":"296","SHORT_NAME":"Cambridge (IGCSE)","DOMAIN_NAME":"STEM"},{"CONT_ID":"368","CATEGORY_ID":"1","CONT_TITLE":"Oxidation-Reduction Reactions","CONT_SLUG":"oxidation-reduction-reaction","CONT_TITLE_AR":"Oxidation-Reduction Reaction","CONT_DESC":"\u003Ch3\u003EOverview:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EBoth oxidation and reduction take place in a singe reaction, called a redox reaction. The chemical species undergoing oxidation is called an oxidant or reducing agent. The chemical species undergoing reduction is called a reductant or oxidizing agent.\u003C\/div\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Ch3\u003ELearning Objectives:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EAfter completing this module, you will be able to:\u003C\/div\u003E \r\n\u003Cdiv\u003E- Identify oxidation-reduction or redox reactions.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Identify a redox reaction.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Identify the oxidizing and reducing agents in a redox reaction.\u003C\/div\u003E","CONT_DESC_AR":"In a redox reaction both oxidation and reduction takes place in a single reaction. The chemical species undergoing oxidation is called an oxidant or reducing agent. The chemical species undergoing reduction is called a reductant or oxidizing agent.\u0026lt;br \/\u0026gt;\n\u0026lt;br \/\u0026gt;\n\u0026lt;strong\u0026gt;Learning Objectives\u0026lt;\/strong\u0026gt;\u0026lt;br \/\u0026gt;\n\u0026lt;br \/\u0026gt;\nIn this simulation, you will be able to:\u0026lt;br \/\u0026gt;\n\u0026amp;bull; define oxidation-reduction (redox) reactions\u0026lt;br \/\u0026gt;\n\u0026amp;bull; identify a redox reaction\u0026lt;br \/\u0026gt;\n\u0026amp;bull; identify the oxidizing and reducing agents in a redox reaction","BACKING_FILE":null,"FILE_UID":null,"SCORM_COURSE_ID":null,"CONT_SRC":"","MOD_FILES":null,"FOLDER_NAME":null,"CONTTYPE_ID":"9","ANDROID_PKG":"com.umety.vr.ss200026","TOPIC_ID":"ss200026","IS_PUBLISH":"Y","IS_PUBLIC":"Y","CONT_PRICE":null,"PUBLIC_IMG":"thumb_SS200026.jpg","PUBLIC_BANNER_IMG":"SS200026.jpg","PUBLIC_VIDEO":"pvideo_ss200026.mp4","PUBLIC_VIDEO_URL":"https:\/\/youtu.be\/frc5RvK7rIk","DIST":null,"SHOW_ON_HOME":"N","CONTROLLER_REQUIRED":"Y","DOMAIN":"3","CONCEPT":"0","STATUS":"A","EXPIRY_DAYS":null,"CREATED_ON":"2018-01-19 07:16:38","CREATED_BY":"1","UPDATED_ON":"0000-00-00 00:00:00","UPDATED_BY":"2","CONT_ORDER":"0","X_ROTATION":null,"Y_ROTATION":null,"Z_ROTATION":null,"BG_COLOR":"0x000000","X_POSITION":null,"Y_POSITION":null,"Z_POSITION":null,"TEMP_DESC":"\u0026lt;div\u0026gt;Overview:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;Both oxidation and reduction take place in a singe reaction, called a redox reaction. The chemical species undergoing oxidation is called an oxidant or reducing agent. The chemical species undergoing reduction is called a reductant or oxidizing agent.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;Learning Objectives:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;div\u0026gt;After completing this module, you will be able to:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Identify oxidation-reduction or redox reactions.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Identify a redox reaction.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Identify the oxidizing and reducing agents in a redox reaction.\u0026lt;\/div\u0026gt;\u0026lt;\/div\u0026gt;","IS_ANALYTICS":"Y","VR_ENABLE":"Y","VR_SESSION_ENABLE":"Y","YOUTUBE_URL":null,"CONT_TYPE":"VR Module","CAT_NAME":"Oxidation-reduction reactions","ADMSUBJECT_ID":"820","ADMCOURSE_ID":"217","DISPLAY_NAME":"Cambridge - AS \u0026 A level - Chemistry","DISPLAY_NAME_AR":"Cambridge - AS \u0026 A level - Chemistry","SUBJECT_NAME":"Chemistry","SUBJECT_NAME_AR":"Chemistry","SUBJECT_DESC":"Chemistry","SUBJECT_DESC_AR":"Chemistry","SUBJECT_IMG":"","SUBJECT_BANNER_IMG":null,"SUBJECT_PRICE":null,"IS_FEATURED":"N","COURSE_NAME":"AS \u0026 A level","COUNTRY_ID":"296","SHORT_NAME":"Cambridge (IGCSE)","DOMAIN_NAME":"STEM"},{"CONT_ID":"356","CATEGORY_ID":"1","CONT_TITLE":"The pH Scale","CONT_SLUG":"the-ph-scale","CONT_TITLE_AR":"The pH Scale","CONT_DESC":"\u003Ch3\u003EOverview:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EThe pH scale ranges from 0 to 14. Aqueous solutions with a pH of less than 7 are acidic. Aqueous solutions with pH more than 7 are basic. Aqueous solutions with a pH exactly equal to 7 are neutral. Acidity increases as the solution move below 7, with pH 1 being the most acidic. Basicity increases as the solution move above 7, with pH 14 being the most basic.\u003C\/div\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Ch3\u003ELearning Objectives:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EAfter completing this module, you will be able to:\u003C\/div\u003E \r\n\u003Cdiv\u003E- Describe the pH scale.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Compare different acids, bases and neutral solutions on the pH scale.\u003C\/div\u003E","CONT_DESC_AR":"The pH scale ranges from 0 to 14. Aqueous solutions with a pH of less than 7 are acidic. Aqueous solutions with pH more than 7 are basic. Aqueous solutions with a pH exactly equal to 7 are neutral. Acidity increases as we move below 7, with pH 1 being the most acidic. Basicity increases as we move above 7, with pH 14 being the most basic.\u0026lt;br \/\u0026gt;\n\u0026lt;br \/\u0026gt;\n\u0026lt;strong\u0026gt;Learning Objectives\u0026lt;\/strong\u0026gt;\u0026lt;br \/\u0026gt;\n\u0026lt;br \/\u0026gt;\nIn this simulation you will be able to:\u0026lt;br \/\u0026gt;\n\u0026amp;bull; define the pH scale\u0026lt;br \/\u0026gt;\n\u0026amp;bull; compare different acids, bases and neutral solutions in a pH scale","BACKING_FILE":null,"FILE_UID":null,"SCORM_COURSE_ID":null,"CONT_SRC":"","MOD_FILES":null,"FOLDER_NAME":null,"CONTTYPE_ID":"9","ANDROID_PKG":"com.umety.vr.ms200067","TOPIC_ID":"ms200067","IS_PUBLISH":"Y","IS_PUBLIC":"Y","CONT_PRICE":null,"PUBLIC_IMG":"thumb_MS200067.jpg","PUBLIC_BANNER_IMG":"MS200067.jpg","PUBLIC_VIDEO":"pvideo_ms200067.mp4","PUBLIC_VIDEO_URL":"https:\/\/youtu.be\/9cl_CJSsVww","DIST":null,"SHOW_ON_HOME":"N","CONTROLLER_REQUIRED":"Y","DOMAIN":"3","CONCEPT":"0","STATUS":"A","EXPIRY_DAYS":null,"CREATED_ON":"2018-01-19 07:16:38","CREATED_BY":"1","UPDATED_ON":"0000-00-00 00:00:00","UPDATED_BY":"2","CONT_ORDER":"0","X_ROTATION":null,"Y_ROTATION":null,"Z_ROTATION":null,"BG_COLOR":"0x000000","X_POSITION":null,"Y_POSITION":null,"Z_POSITION":null,"TEMP_DESC":"Overview:\u0026lt;br\u0026gt;\u0026lt;br\u0026gt;The pH scale ranges from 0 to 14. Aqueous solutions with a pH of less than 7 are acidic. Aqueous solutions with pH more than 7 are basic. Aqueous solutions with a pH exactly equal to 7 are neutral. Acidity increases as the solution move below 7, with pH 1 being the most acidic. Basicity increases as the solution move above 7, with pH 14 being the most basic.\u0026lt;br\u0026gt;\u0026lt;br\u0026gt;Learning objectives\u0026lt;br\u0026gt;\u0026lt;br\u0026gt;\u0026lt;div\u0026gt;After completing this module, you will be able to:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Describe the pH scale.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Compare different acids, bases and neutral solutions on the pH scale.\u0026lt;\/div\u0026gt;","IS_ANALYTICS":"Y","VR_ENABLE":"Y","VR_SESSION_ENABLE":"Y","YOUTUBE_URL":null,"CONT_TYPE":"VR Module","CAT_NAME":"The pH scale","ADMSUBJECT_ID":"820","ADMCOURSE_ID":"217","DISPLAY_NAME":"Cambridge - AS \u0026 A level - Chemistry","DISPLAY_NAME_AR":"Cambridge - AS \u0026 A level - Chemistry","SUBJECT_NAME":"Chemistry","SUBJECT_NAME_AR":"Chemistry","SUBJECT_DESC":"Chemistry","SUBJECT_DESC_AR":"Chemistry","SUBJECT_IMG":"","SUBJECT_BANNER_IMG":null,"SUBJECT_PRICE":null,"IS_FEATURED":"N","COURSE_NAME":"AS \u0026 A level","COUNTRY_ID":"296","SHORT_NAME":"Cambridge (IGCSE)","DOMAIN_NAME":"STEM"},{"CONT_ID":"355","CATEGORY_ID":"1","CONT_TITLE":"What is pH?","CONT_SLUG":"what-is-ph","CONT_TITLE_AR":"What is pH?","CONT_DESC":"\u003Ch3\u003EOverview:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EThe pH level is a numeric scale used to specify the acidity or basicity of an aqueous solution. Solutions with a pH less than 7 are acidic and solutions with a pH greater than 7 are basic. Pure water is neutral, at pH 7, being neither an acid nor a base.\u003C\/div\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Ch3\u003ELearning Objectives:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EAfter completing this module, you will be able to:\u003C\/div\u003E \r\n\u003Cdiv\u003E- Explain the difference between acidic, basic, and neutral solutions on the basis of their pH value.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Classify solutions as acidic or basic based on their pH values.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Identify the relationship between hydronium ion concentration and pH value.\u003C\/div\u003E","CONT_DESC_AR":"The pH level is a numeric scale used to specify the acidity or basicity of an aqueous solution. Solutions with a pH less than 7 are acidic and solutions with a pH greater than 7 are basic. Pure water is neutral, at pH 7, being neither an acid nor a base.\u0026lt;br \/\u0026gt;\n\u0026lt;br \/\u0026gt;\n\u0026lt;strong\u0026gt;Learning Objectives\u0026lt;\/strong\u0026gt;\u0026lt;br \/\u0026gt;\n\u0026lt;br \/\u0026gt;\nIn this simulation , you will be able to:\u0026lt;br \/\u0026gt;\n\u0026amp;bull; define the pH of an aqueous solution and its importance\u0026lt;br \/\u0026gt;\n\u0026amp;bull; memorize the application of pH\u0026lt;br \/\u0026gt;\n\u0026amp;bull; calculate pH for a given concentration of hydronium ion","BACKING_FILE":null,"FILE_UID":null,"SCORM_COURSE_ID":null,"CONT_SRC":"","MOD_FILES":null,"FOLDER_NAME":null,"CONTTYPE_ID":"9","ANDROID_PKG":"com.umety.vr.ms200066","TOPIC_ID":"ms200066","IS_PUBLISH":"Y","IS_PUBLIC":"Y","CONT_PRICE":null,"PUBLIC_IMG":"thumb_MS200066.jpg","PUBLIC_BANNER_IMG":"MS200066.jpg","PUBLIC_VIDEO":"pvideo_ms200066.mp4","PUBLIC_VIDEO_URL":"https:\/\/youtu.be\/OFZ9pgaM2so","DIST":null,"SHOW_ON_HOME":"N","CONTROLLER_REQUIRED":"Y","DOMAIN":"3","CONCEPT":"0","STATUS":"A","EXPIRY_DAYS":null,"CREATED_ON":"2018-01-19 07:16:38","CREATED_BY":"1","UPDATED_ON":"0000-00-00 00:00:00","UPDATED_BY":"2","CONT_ORDER":"0","X_ROTATION":null,"Y_ROTATION":null,"Z_ROTATION":null,"BG_COLOR":"0x000000","X_POSITION":null,"Y_POSITION":null,"Z_POSITION":null,"TEMP_DESC":"Overview:\u0026lt;br\u0026gt;\u0026lt;br\u0026gt;The pH level is a numeric scale used to specify the acidity or basicity of an aqueous solution. Solutions with a pH less than 7 are acidic and solutions with a pH greater than 7 are basic. Pure water is neutral, at pH 7, being neither an acid nor a base.\u0026lt;br\u0026gt;\u0026lt;br\u0026gt;Learning objectives\u0026lt;br\u0026gt;\u0026lt;br\u0026gt;\u0026lt;div\u0026gt;After completing this module, you will be able to:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Explain the difference between acidic, basic, and neutral solutions on the basis of their pH value.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Classify solutions as acidic or basic based on their pH values.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Identify the relationship between hydronium ion concentration and pH value.\u0026lt;\/div\u0026gt;","IS_ANALYTICS":"Y","VR_ENABLE":"Y","VR_SESSION_ENABLE":"Y","YOUTUBE_URL":null,"CONT_TYPE":"VR Module","CAT_NAME":"What is pH?","ADMSUBJECT_ID":"820","ADMCOURSE_ID":"217","DISPLAY_NAME":"Cambridge - AS \u0026 A level - Chemistry","DISPLAY_NAME_AR":"Cambridge - AS \u0026 A level - Chemistry","SUBJECT_NAME":"Chemistry","SUBJECT_NAME_AR":"Chemistry","SUBJECT_DESC":"Chemistry","SUBJECT_DESC_AR":"Chemistry","SUBJECT_IMG":"","SUBJECT_BANNER_IMG":null,"SUBJECT_PRICE":null,"IS_FEATURED":"N","COURSE_NAME":"AS \u0026 A level","COUNTRY_ID":"296","SHORT_NAME":"Cambridge (IGCSE)","DOMAIN_NAME":"STEM"},{"CONT_ID":"353","CATEGORY_ID":"1","CONT_TITLE":"The Atom","CONT_SLUG":"the-atom","CONT_TITLE_AR":"The Atom","CONT_DESC":"\u003Ch3\u003EOverview:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EAn atom is the smallest particle that defines an element. Atoms are made up of three subatomic particles: electrons, protons and neutrons. Protons and neutrons are present in a small, dense nucleus at the center of the atom. The positively charged nucleus is surrounded by negatively charged electrons.\u003C\/div\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Ch3\u003ELearning Objectives:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EAfter completing this module, you will be able to:\u003C\/div\u003E \r\n\u003Cdiv\u003E- Define an atom.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Describe subatomic particles.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Explain the subatomic particles that are present in the nucleus.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Explain the subatomic particles that revolve around the nucleus.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Construct a model of an atom.\u003C\/div\u003E","CONT_DESC_AR":"An atom is the smallest particle that makes up all matter. Atoms are made up of three subatomic particles: electrons, protons and neutrons. Protons and neutrons are present a in a small, dense nucleus at the center of the atom. The positively charged nucleus is surrounded by negatively charged electrons.\u0026lt;br \/\u0026gt;\n\u0026amp;nbsp;\u0026lt;br \/\u0026gt;\n\u0026lt;strong\u0026gt;Learning Objectives\u0026lt;\/strong\u0026gt;\u0026lt;br \/\u0026gt;\n\u0026lt;br \/\u0026gt;\nIn this simulation, you will be able to:\n\u0026lt;ol\u0026gt;\n\t\u0026lt;li value=\u0026quot;NaN\u0026quot;\u0026gt;define an atom\u0026lt;\/li\u0026gt;\n\t\u0026lt;li value=\u0026quot;NaN\u0026quot;\u0026gt;describe subatomic particles\u0026lt;\/li\u0026gt;\n\t\u0026lt;li value=\u0026quot;NaN\u0026quot;\u0026gt;explain subatomic particles that are present in the nucleus\u0026lt;\/li\u0026gt;\n\t\u0026lt;li value=\u0026quot;NaN\u0026quot;\u0026gt;explain subatomic particle that revolve around the nucleus\u0026lt;\/li\u0026gt;\n\t\u0026lt;li value=\u0026quot;NaN\u0026quot;\u0026gt;construct the model of an atom\u0026lt;\/li\u0026gt;\n\u0026lt;\/ol\u0026gt;\n","BACKING_FILE":null,"FILE_UID":null,"SCORM_COURSE_ID":null,"CONT_SRC":"","MOD_FILES":null,"FOLDER_NAME":null,"CONTTYPE_ID":"9","ANDROID_PKG":"com.umety.vr.ms200081","TOPIC_ID":"ms200081","IS_PUBLISH":"Y","IS_PUBLIC":"Y","CONT_PRICE":null,"PUBLIC_IMG":"thumb_MS200081.jpg","PUBLIC_BANNER_IMG":"MS200081.jpg","PUBLIC_VIDEO":"pvideo_ms200081.mp4","PUBLIC_VIDEO_URL":"https:\/\/youtu.be\/Y31lr9Sup5A","DIST":null,"SHOW_ON_HOME":"N","CONTROLLER_REQUIRED":"Y","DOMAIN":"3","CONCEPT":"0","STATUS":"A","EXPIRY_DAYS":null,"CREATED_ON":"2018-01-19 07:16:38","CREATED_BY":"1","UPDATED_ON":"0000-00-00 00:00:00","UPDATED_BY":"2","CONT_ORDER":"0","X_ROTATION":null,"Y_ROTATION":null,"Z_ROTATION":null,"BG_COLOR":"0x000000","X_POSITION":null,"Y_POSITION":null,"Z_POSITION":null,"TEMP_DESC":"Overview:\u0026lt;br\u0026gt;\u0026lt;br\u0026gt;An atom is the smallest particle that defines an element. Atoms are made up of three subatomic particles: electrons, protons and neutrons. Protons and neutrons are present in a small, dense nucleus at the center of the atom. The positively charged nucleus is surrounded by negatively charged electrons.\u0026lt;br\u0026gt;\u0026lt;br\u0026gt;Learning objectives\u0026lt;br\u0026gt;\u0026lt;br\u0026gt;\u0026lt;div\u0026gt;After completing this module, you will be able to:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Define an atom.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Describe subatomic particles.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Explain the subatomic particles that are present in the nucleus.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Explain the subatomic particles that revolve around the nucleus.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Construct a model of an atom.\u0026lt;\/div\u0026gt;\u0026lt;ol\u0026gt;\r\n\u0026lt;\/ol\u0026gt;\r\n","IS_ANALYTICS":"Y","VR_ENABLE":"Y","VR_SESSION_ENABLE":"Y","YOUTUBE_URL":null,"CONT_TYPE":"VR Module","CAT_NAME":"The atom","ADMSUBJECT_ID":"820","ADMCOURSE_ID":"217","DISPLAY_NAME":"Cambridge - AS \u0026 A level - Chemistry","DISPLAY_NAME_AR":"Cambridge - AS \u0026 A level - Chemistry","SUBJECT_NAME":"Chemistry","SUBJECT_NAME_AR":"Chemistry","SUBJECT_DESC":"Chemistry","SUBJECT_DESC_AR":"Chemistry","SUBJECT_IMG":"","SUBJECT_BANNER_IMG":null,"SUBJECT_PRICE":null,"IS_FEATURED":"N","COURSE_NAME":"AS \u0026 A level","COUNTRY_ID":"296","SHORT_NAME":"Cambridge (IGCSE)","DOMAIN_NAME":"STEM"},{"CONT_ID":"333","CATEGORY_ID":"1","CONT_TITLE":"pH Indicators","CONT_SLUG":"ph-indicators","CONT_TITLE_AR":"pH indicators","CONT_DESC":"\u003Ch3\u003EOverview:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EA pH indicator is a halochromic substance that changes color with a change in the pH of a solution. Hence, a pH indicator detects a change in concentration of hydronium ion during a chemical reaction.\u003C\/div\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Ch3\u003ELearning Objectives:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EAfter completing this module, you will be able to:\u003C\/div\u003E \r\n\u003Cdiv\u003E- Identify the change in color of pH indicators at different pH values.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Select an appropriate pH indicator to identify a solution as acidic, basic, or neutral.\u003C\/div\u003E","CONT_DESC_AR":"A pH indicator is a halochromic substance that changes color with a change in the pH of a solution. Hence a pH indicator detects a change concentration of hydronium ion during a chemical reaction.\u0026lt;br \/\u0026gt;\n\u0026lt;br \/\u0026gt;\n\u0026lt;strong\u0026gt;Learning Objectives\u0026lt;\/strong\u0026gt;\u0026lt;br \/\u0026gt;\n\u0026lt;br \/\u0026gt;\nIn this simulation you will be able to:\u0026lt;br \/\u0026gt;\n\u0026amp;bull; identify colour change of an indicator at different pH values\u0026lt;br \/\u0026gt;\n\u0026amp;bull; select an appropriate pH indicator that can be used to identify a solution as acidic, basic or neutral","BACKING_FILE":"ms200068.apk","FILE_UID":null,"SCORM_COURSE_ID":null,"CONT_SRC":"","MOD_FILES":null,"FOLDER_NAME":null,"CONTTYPE_ID":"9","ANDROID_PKG":"com.umety.vr.ms200068","TOPIC_ID":"ms200068","IS_PUBLISH":"Y","IS_PUBLIC":"Y","CONT_PRICE":null,"PUBLIC_IMG":"thumb_MS200068.jpg","PUBLIC_BANNER_IMG":"MS200068.jpg","PUBLIC_VIDEO":"pvideo_ms200068.mp4","PUBLIC_VIDEO_URL":"https:\/\/youtu.be\/QKXjIrQuCYU","DIST":null,"SHOW_ON_HOME":"N","CONTROLLER_REQUIRED":"Y","DOMAIN":"3","CONCEPT":"0","STATUS":"A","EXPIRY_DAYS":null,"CREATED_ON":"2018-01-19 07:16:38","CREATED_BY":"1","UPDATED_ON":"0000-00-00 00:00:00","UPDATED_BY":"2","CONT_ORDER":"0","X_ROTATION":null,"Y_ROTATION":null,"Z_ROTATION":null,"BG_COLOR":"0x000000","X_POSITION":null,"Y_POSITION":null,"Z_POSITION":null,"TEMP_DESC":"Overview:\u0026lt;br\u0026gt;\u0026lt;br\u0026gt;A pH indicator is a halochromic substance that changes color with a change in the pH of a solution. Hence, a pH indicator detects a change in concentration of hydronium ion during a chemical reaction.\u0026lt;br\u0026gt;\u0026lt;br\u0026gt;Learning objectives\u0026lt;br\u0026gt;\u0026lt;br\u0026gt;\u0026lt;div\u0026gt;After completing this module, you will be able to:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Identify the change in color of pH indicators at different pH values.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Select an appropriate pH indicator to identify a solution as acidic, basic, or neutral.\u0026lt;\/div\u0026gt;","IS_ANALYTICS":"Y","VR_ENABLE":"Y","VR_SESSION_ENABLE":"Y","YOUTUBE_URL":null,"CONT_TYPE":"VR Module","CAT_NAME":"pH indicators","ADMSUBJECT_ID":"820","ADMCOURSE_ID":"217","DISPLAY_NAME":"Cambridge - AS \u0026 A level - Chemistry","DISPLAY_NAME_AR":"Cambridge - AS \u0026 A level - Chemistry","SUBJECT_NAME":"Chemistry","SUBJECT_NAME_AR":"Chemistry","SUBJECT_DESC":"Chemistry","SUBJECT_DESC_AR":"Chemistry","SUBJECT_IMG":"","SUBJECT_BANNER_IMG":null,"SUBJECT_PRICE":null,"IS_FEATURED":"N","COURSE_NAME":"AS \u0026 A level","COUNTRY_ID":"296","SHORT_NAME":"Cambridge (IGCSE)","DOMAIN_NAME":"STEM"},{"CONT_ID":"325","CATEGORY_ID":"1","CONT_TITLE":"Atoms and Their Symbols","CONT_SLUG":"atoms-and-their-symbols","CONT_TITLE_AR":"Atoms and Their Symbols","CONT_DESC":"\u003Ch3\u003EOverview:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EThere are over a hundred different types of atoms, and these are called elements. Each element has a special name. For example carbon, oxygen and hydrogen are all elements. Each element is given its own chemical symbol, like O for oxygen and Cl for chlorine. Chemical symbols are usually one or two letters long, but sometimes three letters are used.\u003C\/div\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Ch3\u003ELearning Objectives:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EAfter completing this module, you will be able to:\u003C\/div\u003E \r\n\u003Cdiv\u003E- Identify element symbols.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Write element symbols.\u003C\/div\u003E","CONT_DESC_AR":"There are over a hundred different types of atom, and these are called elements. Each element has a special name. For example carbon, oxygen and hydrogen are all elements. Each element is given its own chemical symbol, like O for oxygen and Cl for chlorine. Chemical symbols are usually one or two letters long, but sometimes three letters are used.\u0026lt;br \/\u0026gt;\n\u0026lt;br \/\u0026gt;\n\u0026lt;strong\u0026gt;Learning Objectives\u0026lt;\/strong\u0026gt;\u0026lt;br \/\u0026gt;\n\u0026lt;br \/\u0026gt;\nIn this simulation, you will be able to:\u0026lt;br \/\u0026gt;\n\u0026amp;bull; identify symbols of the elements\u0026lt;br \/\u0026gt;\n\u0026amp;bull; write symbols of the elements","BACKING_FILE":null,"FILE_UID":null,"SCORM_COURSE_ID":null,"CONT_SRC":"","MOD_FILES":null,"FOLDER_NAME":null,"CONTTYPE_ID":"9","ANDROID_PKG":"com.umety.vr.ms200008","TOPIC_ID":"ms200008","IS_PUBLISH":"Y","IS_PUBLIC":"Y","CONT_PRICE":null,"PUBLIC_IMG":"thumb_MS200008.jpg","PUBLIC_BANNER_IMG":"MS200008.jpg","PUBLIC_VIDEO":"pvideo_ms200008.mp4","PUBLIC_VIDEO_URL":"https:\/\/youtu.be\/vsVEy0BjH3I","DIST":null,"SHOW_ON_HOME":"N","CONTROLLER_REQUIRED":"Y","DOMAIN":"3","CONCEPT":"0","STATUS":"A","EXPIRY_DAYS":null,"CREATED_ON":"2018-01-19 07:16:38","CREATED_BY":"0","UPDATED_ON":"0000-00-00 00:00:00","UPDATED_BY":"2","CONT_ORDER":"0","X_ROTATION":null,"Y_ROTATION":null,"Z_ROTATION":null,"BG_COLOR":"0x000000","X_POSITION":null,"Y_POSITION":null,"Z_POSITION":null,"TEMP_DESC":"\u0026lt;div\u0026gt;Overview:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;div\u0026gt;There are over a hundred different types of atoms, and these are called elements. Each element has a special name. For example carbon, oxygen and hydrogen are all elements. Each element is given its own chemical symbol, like O for oxygen and Cl for chlorine. Chemical symbols are usually one or two letters long, but sometimes three letters are used.\u0026lt;\/div\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;Learning Objectives:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;div\u0026gt;After completing this module, you will be able to:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Identify element symbols.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Write element symbols.\u0026lt;\/div\u0026gt;\u0026lt;\/div\u0026gt;","IS_ANALYTICS":"Y","VR_ENABLE":"Y","VR_SESSION_ENABLE":"Y","YOUTUBE_URL":null,"CONT_TYPE":"VR Module","CAT_NAME":"Atoms and Their Symbols","ADMSUBJECT_ID":"820","ADMCOURSE_ID":"217","DISPLAY_NAME":"Cambridge - AS \u0026 A level - Chemistry","DISPLAY_NAME_AR":"Cambridge - AS \u0026 A level - Chemistry","SUBJECT_NAME":"Chemistry","SUBJECT_NAME_AR":"Chemistry","SUBJECT_DESC":"Chemistry","SUBJECT_DESC_AR":"Chemistry","SUBJECT_IMG":"","SUBJECT_BANNER_IMG":null,"SUBJECT_PRICE":null,"IS_FEATURED":"N","COURSE_NAME":"AS \u0026 A level","COUNTRY_ID":"296","SHORT_NAME":"Cambridge (IGCSE)","DOMAIN_NAME":"STEM"},{"CONT_ID":"279","CATEGORY_ID":"1","CONT_TITLE":"Structure of Phenol","CONT_SLUG":"structure-of-phenol","CONT_TITLE_AR":"Structure of Phenol","CONT_DESC":"\u003Ch3\u003EOverview:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EIn phenol, hydroxy functional group is directly attached to the sp2 hybridized carbon atom of the benzene ring. The interaction of six unhybridized 2pz orbitals of carbon atoms of the benzene ring leads to the formation of delocalized pi-electron clouds.\u003C\/div\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Ch3\u003ELearning Objectives:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EAfter completing this module, you will be able to:\u003C\/div\u003E \r\n\u003Cdiv\u003E- Identify the functional group present in phenol.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Explain the charge distribution of the phenol molecule using its electrostatic potential map.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Explain the orbital structure of phenol.\u003C\/div\u003E","CONT_DESC_AR":"In phenol hydroxy functional group is directly attached to the sp2 hybridised carbon atom of the benzene ring. The interaction of six unhybridised 2pz orbitals of carbon atoms of the benzene ring leads to the formation of delocalised pi-electron clouds.\u0026lt;br \/\u0026gt;\n\u0026lt;br \/\u0026gt;\n\u0026lt;strong\u0026gt;Learning Objectives\u0026lt;\/strong\u0026gt;\u0026lt;br \/\u0026gt;\n\u0026lt;br \/\u0026gt;\nIn this simulation, you will be able to:\u0026lt;br \/\u0026gt;\n- identify functional groups present in phenol\u0026lt;br \/\u0026gt;\n- explain the charge distribution of the phenol molecule using an electrostatic potential map\u0026lt;br \/\u0026gt;\n- explain the orbital structure of phenol","BACKING_FILE":"ss200049.apk","FILE_UID":null,"SCORM_COURSE_ID":null,"CONT_SRC":"","MOD_FILES":null,"FOLDER_NAME":null,"CONTTYPE_ID":"9","ANDROID_PKG":"com.umety.vr.ss200049","TOPIC_ID":"ss200049","IS_PUBLISH":"Y","IS_PUBLIC":"Y","CONT_PRICE":null,"PUBLIC_IMG":"thumb_SS200049.jpg","PUBLIC_BANNER_IMG":"ss200049.jpg","PUBLIC_VIDEO":"pvideo_ss200049.mp4","PUBLIC_VIDEO_URL":"https:\/\/youtu.be\/y_oKx7y2T7o","DIST":null,"SHOW_ON_HOME":"N","CONTROLLER_REQUIRED":"Y","DOMAIN":"3","CONCEPT":"0","STATUS":"A","EXPIRY_DAYS":null,"CREATED_ON":"2018-01-19 07:16:38","CREATED_BY":"1","UPDATED_ON":"0000-00-00 00:00:00","UPDATED_BY":"2","CONT_ORDER":"0","X_ROTATION":null,"Y_ROTATION":null,"Z_ROTATION":null,"BG_COLOR":"0x000000","X_POSITION":null,"Y_POSITION":null,"Z_POSITION":null,"TEMP_DESC":"\u0026lt;div\u0026gt;Overview:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;In phenol, hydroxy functional group is directly attached to the sp2 hybridized carbon atom of the benzene ring. The interaction of six unhybridized 2pz orbitals of carbon atoms of the benzene ring leads to the formation of delocalized pi-electron clouds.\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;Learning Objectives:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;div\u0026gt;After completing this module, you will be able to:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Identify the functional group present in phenol.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Explain the charge distribution of the phenol molecule using its electrostatic potential map.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Explain the orbital structure of phenol.\u0026lt;\/div\u0026gt;\u0026lt;\/div\u0026gt;","IS_ANALYTICS":"Y","VR_ENABLE":"Y","VR_SESSION_ENABLE":"Y","YOUTUBE_URL":null,"CONT_TYPE":"VR Module","CAT_NAME":"Structure of Phenol","ADMSUBJECT_ID":"820","ADMCOURSE_ID":"217","DISPLAY_NAME":"Cambridge - AS \u0026 A level - Chemistry","DISPLAY_NAME_AR":"Cambridge - AS \u0026 A level - Chemistry","SUBJECT_NAME":"Chemistry","SUBJECT_NAME_AR":"Chemistry","SUBJECT_DESC":"Chemistry","SUBJECT_DESC_AR":"Chemistry","SUBJECT_IMG":"","SUBJECT_BANNER_IMG":null,"SUBJECT_PRICE":null,"IS_FEATURED":"N","COURSE_NAME":"AS \u0026 A level","COUNTRY_ID":"296","SHORT_NAME":"Cambridge (IGCSE)","DOMAIN_NAME":"STEM"},{"CONT_ID":"275","CATEGORY_ID":"1","CONT_TITLE":"Effect of Temperature on Reaction Rate","CONT_SLUG":"effect-of-temperature-on-reaction-rate","CONT_TITLE_AR":"Effect of Temperature on Reaction Rate","CONT_DESC":"\u003Ch3\u003EOverview:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EThe rate of a chemical reaction increases with increase in temperature. For most of the reactions, the rate of reaction becomes nearly double for 10\u00b0 rise in temperature. This increase is mainly due to the increase in the number of collisions of the reactant particles.\u003C\/div\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Ch3\u003ELearning Objectives:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EAfter completing this module, you will be able to:\u003C\/div\u003E \r\n\u003Cdiv\u003E- Explain the increase in the reaction rate with the increase in temperature.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Graphically illustrate the effect of temperature on the reaction rate.\u003C\/div\u003E","CONT_DESC_AR":"The rate of a chemical reaction increases with increase in temperature. For most of the reactions, the rate of reaction becomes nearly double for 10\u0026amp;deg; rise in temperature. This increase is mainly due to the increase in the number of collisions.\u0026lt;br \/\u0026gt;\n\u0026lt;br \/\u0026gt;\n\u0026lt;strong\u0026gt;Learning Objectives\u0026lt;\/strong\u0026gt;\u0026lt;br \/\u0026gt;\n\u0026lt;br \/\u0026gt;\nIn this simulation, you will be able to:\u0026lt;br \/\u0026gt;\n\u0026amp;bull; explain the increase in the reaction rate with the increase in temperature\u0026lt;br \/\u0026gt;\n\u0026amp;bull; graphically illustrate the effect of temperature on the reaction rate\u0026lt;br \/\u0026gt;\n\u0026amp;bull; apply the concept in practical problems","BACKING_FILE":"ss200058.apk","FILE_UID":null,"SCORM_COURSE_ID":null,"CONT_SRC":"","MOD_FILES":null,"FOLDER_NAME":null,"CONTTYPE_ID":"9","ANDROID_PKG":"com.umety.vr.ss200058","TOPIC_ID":"ss200058","IS_PUBLISH":"Y","IS_PUBLIC":"Y","CONT_PRICE":null,"PUBLIC_IMG":"thumb_SS200058.jpg","PUBLIC_BANNER_IMG":"SS200058.jpg","PUBLIC_VIDEO":"pvideo_ss200058.mp4","PUBLIC_VIDEO_URL":"https:\/\/youtu.be\/d7IKyDsgrAA","DIST":null,"SHOW_ON_HOME":"N","CONTROLLER_REQUIRED":"Y","DOMAIN":"3","CONCEPT":"0","STATUS":"A","EXPIRY_DAYS":null,"CREATED_ON":"2018-01-19 07:16:38","CREATED_BY":"1","UPDATED_ON":"0000-00-00 00:00:00","UPDATED_BY":"2","CONT_ORDER":"0","X_ROTATION":null,"Y_ROTATION":null,"Z_ROTATION":null,"BG_COLOR":"0x000000","X_POSITION":null,"Y_POSITION":null,"Z_POSITION":null,"TEMP_DESC":"\u0026lt;div\u0026gt;Overview:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;The rate of a chemical reaction increases with increase in temperature. For most of the reactions, the rate of reaction becomes nearly double for 10\u00b0 rise in temperature. This increase is mainly due to the increase in the number of collisions of the reactant particles.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;Learning Objectives:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;div\u0026gt;After completing this module, you will be able to:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Explain the increase in the reaction rate with the increase in temperature.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Graphically illustrate the effect of temperature on the reaction rate.\u0026lt;\/div\u0026gt;\u0026lt;\/div\u0026gt;","IS_ANALYTICS":"Y","VR_ENABLE":"Y","VR_SESSION_ENABLE":"Y","YOUTUBE_URL":null,"CONT_TYPE":"VR Module","CAT_NAME":"Effect of temperature on reaction rate","ADMSUBJECT_ID":"820","ADMCOURSE_ID":"217","DISPLAY_NAME":"Cambridge - AS \u0026 A level - Chemistry","DISPLAY_NAME_AR":"Cambridge - AS \u0026 A level - Chemistry","SUBJECT_NAME":"Chemistry","SUBJECT_NAME_AR":"Chemistry","SUBJECT_DESC":"Chemistry","SUBJECT_DESC_AR":"Chemistry","SUBJECT_IMG":"","SUBJECT_BANNER_IMG":null,"SUBJECT_PRICE":null,"IS_FEATURED":"N","COURSE_NAME":"AS \u0026 A level","COUNTRY_ID":"296","SHORT_NAME":"Cambridge (IGCSE)","DOMAIN_NAME":"STEM"},{"CONT_ID":"273","CATEGORY_ID":"1","CONT_TITLE":"Structural Representations of Organic Compounds","CONT_SLUG":"structural-representations-of-organic-compounds","CONT_TITLE_AR":"Structural Representations of Organic Compounds","CONT_DESC":"\u003Ch3\u003EOverview:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EVarious structural representations used to represent organic compounds include complete structural formula, bond-line structural formula and polygon formula. Molecular models are used for better visualization and perception of 3D structures of organic molecules.\u003C\/div\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Ch3\u003ELearning Objectives:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EAfter completing this module, you will be able to:\u003C\/div\u003E \r\n\u003Cdiv\u003E- Explain various structural representations such as molecular formula, structural formula, and bond-line formula used to represent organic compounds.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Explain ball and stick models and space filling models of organic compounds.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Compare the molecular formula, structural formula, bond-line formula, and ball and stick model.\u003C\/div\u003E","CONT_DESC_AR":"Various structural representations used to represent organic compounds include complete structural formula, bond-line structural formula and polygon formula. Molecular models are used for better visualisation and perception of 3D structures of organic molecules.\u0026lt;br \/\u0026gt;\n\u0026amp;nbsp;\u0026lt;br \/\u0026gt;\n\u0026lt;strong\u0026gt;Learning Objectives\u0026lt;\/strong\u0026gt;\u0026lt;br \/\u0026gt;\n\u0026lt;br \/\u0026gt;\nIn this simulation, you will be able to:\u0026lt;br \/\u0026gt;\n\u0026amp;bull; explain various structural representations such as molecular formula, structural formula, and bond-line formula used to represent organic compounds\u0026lt;br \/\u0026gt;\n\u0026amp;bull; explain ball and stick models and space filling models of organic compounds\u0026amp;nbsp;properties of these allotropes are quite different due to the different arrangements of carbon atoms in their crystals","BACKING_FILE":"ss200057.apk","FILE_UID":null,"SCORM_COURSE_ID":null,"CONT_SRC":"","MOD_FILES":null,"FOLDER_NAME":null,"CONTTYPE_ID":"9","ANDROID_PKG":"com.umety.vr.ss200057","TOPIC_ID":"ss200057","IS_PUBLISH":"Y","IS_PUBLIC":"Y","CONT_PRICE":null,"PUBLIC_IMG":"thumb_SS200057.jpg","PUBLIC_BANNER_IMG":"SS200057.jpg","PUBLIC_VIDEO":"pvideo_ss200057.mp4","PUBLIC_VIDEO_URL":"https:\/\/youtu.be\/40m-Blnmh74","DIST":null,"SHOW_ON_HOME":"N","CONTROLLER_REQUIRED":"Y","DOMAIN":"3","CONCEPT":"0","STATUS":"A","EXPIRY_DAYS":null,"CREATED_ON":"2018-01-19 07:16:38","CREATED_BY":"1","UPDATED_ON":"0000-00-00 00:00:00","UPDATED_BY":"2","CONT_ORDER":"0","X_ROTATION":null,"Y_ROTATION":null,"Z_ROTATION":null,"BG_COLOR":"0x000000","X_POSITION":null,"Y_POSITION":null,"Z_POSITION":null,"TEMP_DESC":"\u0026lt;div\u0026gt;Overview:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;Various structural representations used to represent organic compounds include complete structural formula, bond-line structural formula and polygon formula. Molecular models are used for better visualization and perception of 3D structures of organic molecules.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;Learning Objectives:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;div\u0026gt;After completing this module, you will be able to:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Explain various structural representations such as molecular formula, structural formula, and bond-line formula used to represent organic compounds.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Explain ball and stick models and space filling models of organic compounds.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Compare the molecular formula, structural formula, bond-line formula, and ball and stick model.\u0026lt;\/div\u0026gt;\u0026lt;\/div\u0026gt;","IS_ANALYTICS":"Y","VR_ENABLE":"Y","VR_SESSION_ENABLE":"Y","YOUTUBE_URL":null,"CONT_TYPE":"VR Module","CAT_NAME":"Structural representations of organic compounds","ADMSUBJECT_ID":"820","ADMCOURSE_ID":"217","DISPLAY_NAME":"Cambridge - AS \u0026 A level - Chemistry","DISPLAY_NAME_AR":"Cambridge - AS \u0026 A level - Chemistry","SUBJECT_NAME":"Chemistry","SUBJECT_NAME_AR":"Chemistry","SUBJECT_DESC":"Chemistry","SUBJECT_DESC_AR":"Chemistry","SUBJECT_IMG":"","SUBJECT_BANNER_IMG":null,"SUBJECT_PRICE":null,"IS_FEATURED":"N","COURSE_NAME":"AS \u0026 A level","COUNTRY_ID":"296","SHORT_NAME":"Cambridge (IGCSE)","DOMAIN_NAME":"STEM"},{"CONT_ID":"270","CATEGORY_ID":"1","CONT_TITLE":"Boyle\u2019s Law","CONT_SLUG":"boyles-law","CONT_TITLE_AR":"Boyle\u2019s Law","CONT_DESC":"\u003Ch3\u003EOverview:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EBoyle\u0026#039;s law gives a quantitative relationship between pressure and the volume of a gas. According to this law, at constant temperature, the volume of a given mass of a gas is inversely proportional to its pressure.\u003C\/div\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Ch3\u003ELearning Objectives:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EAfter completing this module, you will be able to:\u003C\/div\u003E \r\n\u003Cdiv\u003E- Explain the quantitative relationship between the pressure and the volume of a gas.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Graphically illustration Boyle\u0026#039;s law.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Apply Boyle\u0026#039;s law in practical problems.\u003C\/div\u003E","CONT_DESC_AR":"Boyles law gives a quantitative relationship between pressure and the volume of a gas. According to this law, at constant temperature, the volume of a given mass of a gas is inversely proportional to its pressure.\u0026lt;br \/\u0026gt;\n\u0026amp;nbsp;\u0026lt;br \/\u0026gt;\n\u0026lt;strong\u0026gt;Learning Objectives\u0026lt;\/strong\u0026gt;\u0026lt;br \/\u0026gt;\n\u0026lt;br \/\u0026gt;\nIn this simulation , you will be able to:\u0026lt;br \/\u0026gt;\n- understand the quantitative relationship between pressure and the volume of a gas\u0026lt;br \/\u0026gt;\n- identify a graphical illustration of Boyles law\u0026lt;br \/\u0026gt;\n- apply Boyles law in practical problems","BACKING_FILE":null,"FILE_UID":null,"SCORM_COURSE_ID":null,"CONT_SRC":"","MOD_FILES":null,"FOLDER_NAME":null,"CONTTYPE_ID":"9","ANDROID_PKG":"com.umety.vr.ss200046","TOPIC_ID":"ss200046","IS_PUBLISH":"Y","IS_PUBLIC":"Y","CONT_PRICE":null,"PUBLIC_IMG":"thumb_SS200046.jpg","PUBLIC_BANNER_IMG":"ss200046.jpg","PUBLIC_VIDEO":"pvideo_ss200046.mp4","PUBLIC_VIDEO_URL":"https:\/\/youtu.be\/K4i5Uy_nk54","DIST":null,"SHOW_ON_HOME":"N","CONTROLLER_REQUIRED":"Y","DOMAIN":"3","CONCEPT":"0","STATUS":"A","EXPIRY_DAYS":null,"CREATED_ON":"2018-01-19 07:16:38","CREATED_BY":"1","UPDATED_ON":"0000-00-00 00:00:00","UPDATED_BY":"2","CONT_ORDER":"0","X_ROTATION":null,"Y_ROTATION":null,"Z_ROTATION":null,"BG_COLOR":"0x000000","X_POSITION":null,"Y_POSITION":null,"Z_POSITION":null,"TEMP_DESC":"\u0026lt;div\u0026gt;Overview:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;div\u0026gt;Boyle\u0026#039;s law gives a quantitative relationship between pressure and the volume of a gas. According to this law, at constant temperature, the volume of a given mass of a gas is inversely proportional to its pressure.\u0026lt;\/div\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;Learning Objectives:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;div\u0026gt;After completing this module, you will be able to:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Explain the quantitative relationship between the pressure and the volume of a gas.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Graphically illustration Boyle\u0026#039;s law.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Apply Boyle\u0026#039;s law in practical problems.\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;\/div\u0026gt;","IS_ANALYTICS":"Y","VR_ENABLE":"Y","VR_SESSION_ENABLE":"Y","YOUTUBE_URL":null,"CONT_TYPE":"VR Module","CAT_NAME":"Boyle\u0027s law","ADMSUBJECT_ID":"820","ADMCOURSE_ID":"217","DISPLAY_NAME":"Cambridge - AS \u0026 A level - Chemistry","DISPLAY_NAME_AR":"Cambridge - AS \u0026 A level - Chemistry","SUBJECT_NAME":"Chemistry","SUBJECT_NAME_AR":"Chemistry","SUBJECT_DESC":"Chemistry","SUBJECT_DESC_AR":"Chemistry","SUBJECT_IMG":"","SUBJECT_BANNER_IMG":null,"SUBJECT_PRICE":null,"IS_FEATURED":"N","COURSE_NAME":"AS \u0026 A level","COUNTRY_ID":"296","SHORT_NAME":"Cambridge (IGCSE)","DOMAIN_NAME":"STEM"},{"CONT_ID":"268","CATEGORY_ID":"1","CONT_TITLE":"Charles\u2019s Law","CONT_SLUG":"charles-law","CONT_TITLE_AR":"Charles\u2019s Law","CONT_DESC":"\u003Ch3\u003EOverview:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003ECharles\u0026#039;s law provides a quantitative relationship between the volume and temperature of a gas. According to this law, at constant pressure, the volume of a given mass of a gas is directly proportional to its temperature.\u003C\/div\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Ch3\u003ELearning Objectives:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EAfter completing this module, you will be able to:\u003C\/div\u003E \r\n\u003Cdiv\u003E- Explain the quantitative relationship between the temperature and volume of a gas.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Graphically illustrate Charles\u0026#039;s law.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Apply Charles\u0026#039;s law in practical problems.\u003C\/div\u003E","CONT_DESC_AR":"Charless law provides a quantitative relationship between volume and the temperature of a gas. According to this law, at constant pressure, the volume of a given mass of a gas is directly proportional to its temperature.\u0026lt;br \/\u0026gt;\n\u0026lt;br \/\u0026gt;\n\u0026lt;strong\u0026gt;Learning Objectives\u0026lt;\/strong\u0026gt;\u0026lt;br \/\u0026gt;\n\u0026lt;br \/\u0026gt;\nIn this simulation you will be able to:\u0026lt;br \/\u0026gt;\n\u0026amp;bull; explain the quantitative relationship between temperature and volume of a gas\u0026lt;br \/\u0026gt;\n\u0026amp;bull; graphically illustrate Charles\u0026amp;#39;s law\u0026lt;br \/\u0026gt;\n\u0026amp;bull; apply Charles\u0026amp;#39;s law in practical problems","BACKING_FILE":null,"FILE_UID":null,"SCORM_COURSE_ID":null,"CONT_SRC":"","MOD_FILES":null,"FOLDER_NAME":null,"CONTTYPE_ID":"9","ANDROID_PKG":"com.umety.vr.ss200045","TOPIC_ID":"ss200045","IS_PUBLISH":"Y","IS_PUBLIC":"Y","CONT_PRICE":null,"PUBLIC_IMG":"thumb_SS200045.jpg","PUBLIC_BANNER_IMG":"SS200045.jpg","PUBLIC_VIDEO":"pvideo_ss200045.mp4","PUBLIC_VIDEO_URL":"https:\/\/youtu.be\/SpjYUcmK_Ro","DIST":null,"SHOW_ON_HOME":"N","CONTROLLER_REQUIRED":"Y","DOMAIN":"3","CONCEPT":"0","STATUS":"A","EXPIRY_DAYS":null,"CREATED_ON":"2018-01-19 07:16:38","CREATED_BY":"1","UPDATED_ON":"0000-00-00 00:00:00","UPDATED_BY":"2","CONT_ORDER":"0","X_ROTATION":null,"Y_ROTATION":null,"Z_ROTATION":null,"BG_COLOR":"0x000000","X_POSITION":null,"Y_POSITION":null,"Z_POSITION":null,"TEMP_DESC":"\u0026lt;div\u0026gt;Overview:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;div\u0026gt;Charles\u0026#039;s law provides a quantitative relationship between the volume and temperature of a gas. According to this law, at constant pressure, the volume of a given mass of a gas is directly proportional to its temperature.\u0026lt;\/div\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;Learning Objectives:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;div\u0026gt;After completing this module, you will be able to:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Explain the quantitative relationship between the temperature and volume of a gas.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Graphically illustrate Charles\u0026#039;s law.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Apply Charles\u0026#039;s law in practical problems.\u0026lt;\/div\u0026gt;\u0026lt;\/div\u0026gt;","IS_ANALYTICS":"Y","VR_ENABLE":"Y","VR_SESSION_ENABLE":"Y","YOUTUBE_URL":null,"CONT_TYPE":"VR Module","CAT_NAME":"Charles\u0027s law","ADMSUBJECT_ID":"820","ADMCOURSE_ID":"217","DISPLAY_NAME":"Cambridge - AS \u0026 A level - Chemistry","DISPLAY_NAME_AR":"Cambridge - AS \u0026 A level - Chemistry","SUBJECT_NAME":"Chemistry","SUBJECT_NAME_AR":"Chemistry","SUBJECT_DESC":"Chemistry","SUBJECT_DESC_AR":"Chemistry","SUBJECT_IMG":"","SUBJECT_BANNER_IMG":null,"SUBJECT_PRICE":null,"IS_FEATURED":"N","COURSE_NAME":"AS \u0026 A level","COUNTRY_ID":"296","SHORT_NAME":"Cambridge (IGCSE)","DOMAIN_NAME":"STEM"},{"CONT_ID":"264","CATEGORY_ID":"1","CONT_TITLE":"Organic Functional Groups","CONT_SLUG":"organic-functional-groups","CONT_TITLE_AR":"Organic Functional Groups","CONT_DESC":"\u003Ch3\u003EOverview:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EA functional group is an atom or group of atoms present in a molecule that largely determines its chemical properties. All compounds containing the same functional group display similar chemical reactions and belong to the same class of organic compounds.\u003C\/div\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Ch3\u003ELearning Objectives:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EAfter completing this module, you will be able to:\u003C\/div\u003E \r\n\u003Cdiv\u003E- Define functional groups.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Identify various functional groups present in organic compounds.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Derive organic compounds containing functional groups from their parent hydrocarbons.\u003C\/div\u003E","CONT_DESC_AR":"A functional group is an atom or group of atoms present in a molecule that largely determines its chemical properties. All compounds containing the same functional group display similar chemical reactions and belong to the same class of organic compounds.\u0026lt;br \/\u0026gt;\n\u0026amp;nbsp;\u0026lt;br \/\u0026gt;\n\u0026lt;strong\u0026gt;Learning Objectives\u0026lt;\/strong\u0026gt;\u0026lt;br \/\u0026gt;\n\u0026lt;br \/\u0026gt;\nIn this simulation, you will be able to:\u0026lt;br \/\u0026gt;\n\u0026amp;bull; define functional groups\u0026lt;br \/\u0026gt;\n\u0026amp;bull; identify various functional groups present in organic compounds\u0026lt;br \/\u0026gt;\n\u0026amp;bull; derive organic compounds containing functional groups from their parent hydrocarbons","BACKING_FILE":"ss200044.apk","FILE_UID":null,"SCORM_COURSE_ID":null,"CONT_SRC":"","MOD_FILES":null,"FOLDER_NAME":null,"CONTTYPE_ID":"9","ANDROID_PKG":"com.umety.vr.ss200044","TOPIC_ID":"ss200044","IS_PUBLISH":"Y","IS_PUBLIC":"Y","CONT_PRICE":null,"PUBLIC_IMG":"thumb_SS200044.jpg","PUBLIC_BANNER_IMG":"SS200044.jpg","PUBLIC_VIDEO":"pvideo_ss200044.mp4","PUBLIC_VIDEO_URL":"https:\/\/youtu.be\/iW10_wefWYQ","DIST":null,"SHOW_ON_HOME":"N","CONTROLLER_REQUIRED":"Y","DOMAIN":"3","CONCEPT":"0","STATUS":"A","EXPIRY_DAYS":null,"CREATED_ON":"2018-01-19 07:16:38","CREATED_BY":"1","UPDATED_ON":"0000-00-00 00:00:00","UPDATED_BY":"2","CONT_ORDER":"0","X_ROTATION":null,"Y_ROTATION":null,"Z_ROTATION":null,"BG_COLOR":"0x000000","X_POSITION":null,"Y_POSITION":null,"Z_POSITION":null,"TEMP_DESC":"\u0026lt;div\u0026gt;Overview:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;A functional group is an atom or group of atoms present in a molecule that largely determines its chemical properties. All compounds containing the same functional group display similar chemical reactions and belong to the same class of organic compounds.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;Learning Objectives:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;div\u0026gt;After completing this module, you will be able to:\u0026amp;nbsp;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Define functional groups.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Identify various functional groups present in organic compounds.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Derive organic compounds containing functional groups from their parent hydrocarbons.\u0026lt;\/div\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;","IS_ANALYTICS":"Y","VR_ENABLE":"Y","VR_SESSION_ENABLE":"Y","YOUTUBE_URL":null,"CONT_TYPE":"VR Module","CAT_NAME":"Organic Functional Groups","ADMSUBJECT_ID":"820","ADMCOURSE_ID":"217","DISPLAY_NAME":"Cambridge - AS \u0026 A level - Chemistry","DISPLAY_NAME_AR":"Cambridge - AS \u0026 A level - Chemistry","SUBJECT_NAME":"Chemistry","SUBJECT_NAME_AR":"Chemistry","SUBJECT_DESC":"Chemistry","SUBJECT_DESC_AR":"Chemistry","SUBJECT_IMG":"","SUBJECT_BANNER_IMG":null,"SUBJECT_PRICE":null,"IS_FEATURED":"N","COURSE_NAME":"AS \u0026 A level","COUNTRY_ID":"296","SHORT_NAME":"Cambridge (IGCSE)","DOMAIN_NAME":"STEM"},{"CONT_ID":"262","CATEGORY_ID":"1","CONT_TITLE":"Structure of Benzene","CONT_SLUG":"structure-of-benzene","CONT_TITLE_AR":"Structure of Benzene","CONT_DESC":"\u003Ch3\u003EOverview:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EThe molecular formula of benzene is C6H6. Kekul\u00e9 proposed that six carbon atoms of benzene are joined to each other by alternate single and double bonds to form a hexagonal ring. The orbital structure of benzene suggests that each carbon atom in benzene ring is sp2 hybridized.\u003C\/div\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Ch3\u003ELearning Objectives:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E  \r\n\u003Cdiv\u003EAfter completing this module, you will be able to:\u003C\/div\u003E \r\n\u003Cdiv\u003E- Identify Kekul\u00e9 structures and the modern symbol of benzene.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Explain the orbital structure of benzene.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Explain the charge distribution of the benzene molecule using its electrostatic potential map.\u003C\/div\u003E","CONT_DESC_AR":"The molecular formula of benzene is C6H6 Kekule proposed that six carbon atoms of benzene are joined to each other by alternate single and double bonds to form a hexagonal ring. The orbital structure of benzene suggests that each carbon atom in benzene ring is sp2\u0026amp;nbsp;hybridised.\u0026lt;br \/\u0026gt;\n\u0026lt;br \/\u0026gt;\n\u0026lt;strong\u0026gt;Learning Objectives\u0026lt;\/strong\u0026gt;\u0026lt;br \/\u0026gt;\n\u0026lt;br \/\u0026gt;\nIn this simulation, you will be able to:\u0026lt;br \/\u0026gt;\n- identify Kekul\u0026amp;eacute; structures and the modern symbol of benzene\u0026lt;br \/\u0026gt;\n- explain the orbital structure of benzene\u0026lt;br \/\u0026gt;\n- explain the charge distribution of the benzene molecule using its electrostatic potential map","BACKING_FILE":"ss200043.apk","FILE_UID":null,"SCORM_COURSE_ID":null,"CONT_SRC":"","MOD_FILES":null,"FOLDER_NAME":null,"CONTTYPE_ID":"9","ANDROID_PKG":"com.umety.vr.ss200043","TOPIC_ID":"ss200043","IS_PUBLISH":"Y","IS_PUBLIC":"Y","CONT_PRICE":null,"PUBLIC_IMG":"thumb_SS200043.jpg","PUBLIC_BANNER_IMG":"SS200043.jpg","PUBLIC_VIDEO":"pvideo_ss200043.mp4","PUBLIC_VIDEO_URL":"https:\/\/youtu.be\/0FPZELqrUf4","DIST":null,"SHOW_ON_HOME":"Y","CONTROLLER_REQUIRED":"Y","DOMAIN":"3","CONCEPT":"0","STATUS":"A","EXPIRY_DAYS":null,"CREATED_ON":"2018-01-19 07:16:38","CREATED_BY":"1","UPDATED_ON":"0000-00-00 00:00:00","UPDATED_BY":"2","CONT_ORDER":"0","X_ROTATION":null,"Y_ROTATION":null,"Z_ROTATION":null,"BG_COLOR":"0x000000","X_POSITION":null,"Y_POSITION":null,"Z_POSITION":null,"TEMP_DESC":"\u0026lt;p\u0026gt;Overview:\u0026lt;\/p\u0026gt;\r\n\u0026lt;p\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/p\u0026gt;\r\n\u0026lt;p\u0026gt;The molecular formula of benzene is C6H6. Kekul\u00e9 proposed that six carbon atoms of benzene are joined to each other by alternate single and double bonds to form a hexagonal ring. The orbital structure of benzene suggests that each carbon atom in benzene ring is sp2 hybridized.\u0026amp;nbsp;\u0026lt;br\u0026gt;\u0026lt;\/p\u0026gt;\r\n\u0026lt;p\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/p\u0026gt;\r\n\u0026lt;p\u0026gt;Learning Objectives:\u0026lt;\/p\u0026gt;\r\n\u0026lt;p\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/p\u0026gt;\r\n\u0026lt;p\u0026gt;After completing this module, you will be able to:\u0026lt;\/p\u0026gt;\u0026lt;p\u0026gt;- Identify Kekul\u00e9 structures and the modern symbol of benzene.\u0026lt;\/p\u0026gt;\u0026lt;p\u0026gt;- Explain the orbital structure of benzene.\u0026lt;\/p\u0026gt;\u0026lt;p\u0026gt;- Explain the charge distribution of the benzene molecule using its electrostatic potential map.\u0026lt;\/p\u0026gt;","IS_ANALYTICS":"Y","VR_ENABLE":"Y","VR_SESSION_ENABLE":"Y","YOUTUBE_URL":null,"CONT_TYPE":"VR Module","CAT_NAME":"Structure of benzene","ADMSUBJECT_ID":"820","ADMCOURSE_ID":"217","DISPLAY_NAME":"Cambridge - AS \u0026 A level - Chemistry","DISPLAY_NAME_AR":"Cambridge - AS \u0026 A level - Chemistry","SUBJECT_NAME":"Chemistry","SUBJECT_NAME_AR":"Chemistry","SUBJECT_DESC":"Chemistry","SUBJECT_DESC_AR":"Chemistry","SUBJECT_IMG":"","SUBJECT_BANNER_IMG":null,"SUBJECT_PRICE":null,"IS_FEATURED":"N","COURSE_NAME":"AS \u0026 A level","COUNTRY_ID":"296","SHORT_NAME":"Cambridge (IGCSE)","DOMAIN_NAME":"STEM"},{"CONT_ID":"259","CATEGORY_ID":"1","CONT_TITLE":"Aromatic Compounds","CONT_SLUG":"aromatic-compound","CONT_TITLE_AR":"Aromatic Compound","CONT_DESC":"\u003Ch3\u003EOverview:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EH\u00fcckel postulated that planar cyclic conjugated polyenes containing delocalized (4n+2) pi-electrons are called aromatic compounds. An example is the benzene molecule, which has 6 \u03c0 electrons is aromatic.\u003C\/div\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Ch3\u003ELearning Objectives:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EAfter completing this module, you will be able to:\u003C\/div\u003E \r\n\u003Cdiv\u003E- Explain the criteria for aromaticity described by H\u00fcckel.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Determine whether a molecule is aromatic or not by investigating its structure.\u003C\/div\u003E","CONT_DESC_AR":"Huckel postulated that planar cyclic conjugated polyenes containing delocalised (4n+2) pi-electrons are called aromatic compounds. An example is the benzene molecule, which has 6\u0026amp;pi; electrons and is aromatic.\u0026lt;br \/\u0026gt;\n\u0026amp;nbsp;\u0026lt;br \/\u0026gt;\n\u0026lt;strong\u0026gt;Learning Objectives\u0026lt;\/strong\u0026gt;\u0026lt;br \/\u0026gt;\n\u0026lt;br \/\u0026gt;\nIn this simulation, you will be able to:\u0026lt;br \/\u0026gt;\n\u0026amp;bull; explain the criteria for aromaticity described by Huckel\u0026lt;br \/\u0026gt;\n\u0026amp;bull; determine whether a molecule is aromatic or not by investigating its structure","BACKING_FILE":"ss200042.apk","FILE_UID":null,"SCORM_COURSE_ID":null,"CONT_SRC":"","MOD_FILES":null,"FOLDER_NAME":null,"CONTTYPE_ID":"9","ANDROID_PKG":"com.umety.vr.ss200042","TOPIC_ID":"ss200042","IS_PUBLISH":"Y","IS_PUBLIC":"Y","CONT_PRICE":null,"PUBLIC_IMG":"thumb_SS200042.jpg","PUBLIC_BANNER_IMG":"SS200042.jpg","PUBLIC_VIDEO":"pvideo_ss200042.mp4","PUBLIC_VIDEO_URL":"https:\/\/youtu.be\/N7AnvZ7Qtqw","DIST":null,"SHOW_ON_HOME":"N","CONTROLLER_REQUIRED":"Y","DOMAIN":"3","CONCEPT":"0","STATUS":"A","EXPIRY_DAYS":null,"CREATED_ON":"2018-01-19 07:16:38","CREATED_BY":"1","UPDATED_ON":"0000-00-00 00:00:00","UPDATED_BY":"2","CONT_ORDER":"0","X_ROTATION":null,"Y_ROTATION":null,"Z_ROTATION":null,"BG_COLOR":"0x000000","X_POSITION":null,"Y_POSITION":null,"Z_POSITION":null,"TEMP_DESC":"\u0026lt;div\u0026gt;Overview:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;H\u00fcckel postulated that planar cyclic conjugated polyenes containing delocalized (4n+2) pi-electrons are called aromatic compounds. An example is the benzene molecule, which has 6 \u03c0 electrons is aromatic.\u0026amp;nbsp;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;Learning Objectives:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;div\u0026gt;After completing this module, you will be able to:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Explain the criteria for aromaticity described by H\u00fcckel.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Determine whether a molecule is aromatic or not by investigating its structure.\u0026lt;\/div\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;","IS_ANALYTICS":"Y","VR_ENABLE":"Y","VR_SESSION_ENABLE":"Y","YOUTUBE_URL":null,"CONT_TYPE":"VR Module","CAT_NAME":"Aromatic Compound","ADMSUBJECT_ID":"820","ADMCOURSE_ID":"217","DISPLAY_NAME":"Cambridge - AS \u0026 A level - Chemistry","DISPLAY_NAME_AR":"Cambridge - AS \u0026 A level - Chemistry","SUBJECT_NAME":"Chemistry","SUBJECT_NAME_AR":"Chemistry","SUBJECT_DESC":"Chemistry","SUBJECT_DESC_AR":"Chemistry","SUBJECT_IMG":"","SUBJECT_BANNER_IMG":null,"SUBJECT_PRICE":null,"IS_FEATURED":"N","COURSE_NAME":"AS \u0026 A level","COUNTRY_ID":"296","SHORT_NAME":"Cambridge (IGCSE)","DOMAIN_NAME":"STEM"},{"CONT_ID":"255","CATEGORY_ID":"1","CONT_TITLE":"Structure of Diamond","CONT_SLUG":"structure-of-diamond","CONT_TITLE_AR":"Structure of Diamond","CONT_DESC":"\u003Ch3\u003EOverview:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EDiamond is a covalent solid in which the carbon atoms are linked together by covalent bonds to give a three dimensional structure. Due to the presence of a strong network of covalent bonds, diamond is very hard and possesses an extremely high melting point.\u003C\/div\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Ch3\u003ELearning Objectives:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EAfter completing this module, you will be able to:\u003C\/div\u003E \r\n\u003Cdiv\u003E- Explain the three dimensional structure of a diamond.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Recognize the type of hybridization of the carbon atoms in a diamond.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Describe the physical properties of a diamond.\u003C\/div\u003E","CONT_DESC_AR":"Diamond is a covalent solid in which the carbon atoms are linked together by covalent bonds to give a three dimensional structure. Due to the presence of a strong network of covalent bonds, diamond is very hard and possesses an extremely high melting point.\u0026lt;br \/\u0026gt;\n\u0026amp;nbsp;\u0026lt;br \/\u0026gt;\n\u0026lt;strong\u0026gt;Learning Objectives\u0026lt;\/strong\u0026gt;\u0026lt;br \/\u0026gt;\n\u0026lt;br \/\u0026gt;\nIn this simulation, you will be able to:\u0026lt;br \/\u0026gt;\n\u0026amp;bull; explain the three dimensional structure of a diamond\u0026lt;br \/\u0026gt;\n\u0026amp;bull; recognize the type of hybridization of the carbon atoms in a diamond\u0026lt;br \/\u0026gt;\n\u0026amp;bull; describe the physical properties of a diamond","BACKING_FILE":"ss200073.apk","FILE_UID":null,"SCORM_COURSE_ID":null,"CONT_SRC":"","MOD_FILES":null,"FOLDER_NAME":null,"CONTTYPE_ID":"9","ANDROID_PKG":"com.umety.vr.ss200073","TOPIC_ID":"ss200073","IS_PUBLISH":"Y","IS_PUBLIC":"Y","CONT_PRICE":null,"PUBLIC_IMG":"thumb_SS200073.jpg","PUBLIC_BANNER_IMG":"SS200073.jpg","PUBLIC_VIDEO":"pvideo_ss200073.mp4","PUBLIC_VIDEO_URL":"https:\/\/youtu.be\/Cnz1zrnl_2U","DIST":null,"SHOW_ON_HOME":"N","CONTROLLER_REQUIRED":"Y","DOMAIN":"3","CONCEPT":"0","STATUS":"A","EXPIRY_DAYS":null,"CREATED_ON":"2018-01-19 07:16:38","CREATED_BY":"1","UPDATED_ON":"0000-00-00 00:00:00","UPDATED_BY":"2","CONT_ORDER":"0","X_ROTATION":null,"Y_ROTATION":null,"Z_ROTATION":null,"BG_COLOR":"0x000000","X_POSITION":null,"Y_POSITION":null,"Z_POSITION":null,"TEMP_DESC":"\u0026lt;div\u0026gt;Overview:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;Diamond is a covalent solid in which the carbon atoms are linked together by covalent bonds to give a three dimensional structure. Due to the presence of a strong network of covalent bonds, diamond is very hard and possesses an extremely high melting point.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;Learning Objectives:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;div\u0026gt;After completing this module, you will be able to:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Explain the three dimensional structure of a diamond.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Recognize the type of hybridization of the carbon atoms in a diamond.\u0026amp;nbsp;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Describe the physical properties of a diamond.\u0026lt;\/div\u0026gt;\u0026lt;\/div\u0026gt;","IS_ANALYTICS":"Y","VR_ENABLE":"Y","VR_SESSION_ENABLE":"Y","YOUTUBE_URL":null,"CONT_TYPE":"VR Module","CAT_NAME":"Structure of diamond","ADMSUBJECT_ID":"820","ADMCOURSE_ID":"217","DISPLAY_NAME":"Cambridge - AS \u0026 A level - Chemistry","DISPLAY_NAME_AR":"Cambridge - AS \u0026 A level - Chemistry","SUBJECT_NAME":"Chemistry","SUBJECT_NAME_AR":"Chemistry","SUBJECT_DESC":"Chemistry","SUBJECT_DESC_AR":"Chemistry","SUBJECT_IMG":"","SUBJECT_BANNER_IMG":null,"SUBJECT_PRICE":null,"IS_FEATURED":"N","COURSE_NAME":"AS \u0026 A level","COUNTRY_ID":"296","SHORT_NAME":"Cambridge (IGCSE)","DOMAIN_NAME":"STEM"},{"CONT_ID":"253","CATEGORY_ID":"1","CONT_TITLE":"Buckyballs","CONT_SLUG":"buckyballs","CONT_TITLE_AR":"Buckyballs","CONT_DESC":"\u003Ch3\u003EOverview:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EBuckyball is an allotrope of carbon containing 60 carbon atoms joined together to form a spherical structure. The structure of buckyball is similar to that of a football as it also contains hexagonal and pentagonal rings.\u003C\/div\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Ch3\u003ELearning Objectives:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EAfter completing this module, you will be able to:\u003C\/div\u003E \r\n\u003Cdiv\u003E- Explain the structure of a buckyball, containing 60 carbon atoms.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Identify the hexagonal and pentagonal rings present in the spherical structure of a buckyball.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Explain the properties of a buckyball.\u003C\/div\u003E","CONT_DESC_AR":"Buckyball is an allotrope of carbon containing 60 carbon atoms joined together to form a spherical structure. The structure of buckyball is similar to that of a football as it also contains hexagonal and pentagonal rings.\u0026lt;br \/\u0026gt;\n\u0026amp;nbsp;\u0026lt;br \/\u0026gt;\n\u0026lt;strong\u0026gt;Learning Objectives\u0026lt;\/strong\u0026gt;\u0026lt;br \/\u0026gt;\n\u0026lt;br \/\u0026gt;\nIn this simulation, you will be able to:\u0026lt;br \/\u0026gt;\n\u0026amp;bull; explain the structure of a buckyball, containing 60 carbon atoms\u0026lt;br \/\u0026gt;\n\u0026amp;bull; identify the hexagonal and pentagonal rings present in the spherical structure of a buckyball\u0026lt;br \/\u0026gt;\n\u0026amp;bull; explain the properties of a buckyball","BACKING_FILE":"ss200056.apk","FILE_UID":null,"SCORM_COURSE_ID":null,"CONT_SRC":"","MOD_FILES":null,"FOLDER_NAME":null,"CONTTYPE_ID":"9","ANDROID_PKG":"com.umety.vr.ss200056","TOPIC_ID":"ss200056","IS_PUBLISH":"Y","IS_PUBLIC":"Y","CONT_PRICE":null,"PUBLIC_IMG":"thumb_SS200056.jpg","PUBLIC_BANNER_IMG":"SS200056.jpg","PUBLIC_VIDEO":"pvideo_ss200056.mp4","PUBLIC_VIDEO_URL":"https:\/\/youtu.be\/EAci6nWM9Q0","DIST":null,"SHOW_ON_HOME":"N","CONTROLLER_REQUIRED":"Y","DOMAIN":"3","CONCEPT":"0","STATUS":"A","EXPIRY_DAYS":null,"CREATED_ON":"2018-01-19 07:16:38","CREATED_BY":"1","UPDATED_ON":"0000-00-00 00:00:00","UPDATED_BY":"2","CONT_ORDER":"0","X_ROTATION":null,"Y_ROTATION":null,"Z_ROTATION":null,"BG_COLOR":"0x000000","X_POSITION":null,"Y_POSITION":null,"Z_POSITION":null,"TEMP_DESC":"\u0026lt;div\u0026gt;Overview:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;Buckyball is an allotrope of carbon containing 60 carbon atoms joined together to form a spherical structure. The structure of buckyball is similar to that of a football as it also contains hexagonal and pentagonal rings.\u0026amp;nbsp;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;Learning Objectives:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;div\u0026gt;After completing this module, you will be able to:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Explain the structure of a buckyball, containing 60 carbon atoms.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Identify the hexagonal and pentagonal rings present in the spherical structure of a buckyball.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Explain the properties of a buckyball.\u0026lt;\/div\u0026gt;\u0026lt;\/div\u0026gt;","IS_ANALYTICS":"Y","VR_ENABLE":"Y","VR_SESSION_ENABLE":"Y","YOUTUBE_URL":null,"CONT_TYPE":"VR Module","CAT_NAME":"Buckyballs","ADMSUBJECT_ID":"820","ADMCOURSE_ID":"217","DISPLAY_NAME":"Cambridge - AS \u0026 A level - Chemistry","DISPLAY_NAME_AR":"Cambridge - AS \u0026 A level - Chemistry","SUBJECT_NAME":"Chemistry","SUBJECT_NAME_AR":"Chemistry","SUBJECT_DESC":"Chemistry","SUBJECT_DESC_AR":"Chemistry","SUBJECT_IMG":"","SUBJECT_BANNER_IMG":null,"SUBJECT_PRICE":null,"IS_FEATURED":"N","COURSE_NAME":"AS \u0026 A level","COUNTRY_ID":"296","SHORT_NAME":"Cambridge (IGCSE)","DOMAIN_NAME":"STEM"},{"CONT_ID":"250","CATEGORY_ID":"1","CONT_TITLE":"The Structure of Graphite","CONT_SLUG":"structure-of-graphite","CONT_TITLE_AR":"Structure of Graphite","CONT_DESC":"\u003Ch3\u003EOverview:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EGraphite is a crystalline allotrope of carbon. The crystalline structure of graphite consists of layers or sheets of carbon atoms. In these layers, each carbon atom is joined to three other carbon atoms by strong covalent bonds to form hexagonal rings. Various graphite layers are held together by weak Van der Waals forces.\u003C\/div\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Ch3\u003ELearning Objectives:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EAfter completing this module, you will be able to:\u003C\/div\u003E \r\n\u003Cdiv\u003E- Explain the layered structure of graphite.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Describe the physical properties of graphite.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Recognize the hybridization of carbon atoms in graphite.\u003C\/div\u003E","CONT_DESC_AR":"Crystal of graphite consists of layers or sheets of carbon atoms. In these layers, each carbon atom is joined to three other carbon atoms by strong covalent bonds to form hexagonal rings. Various graphite layers are held together by weak Van der Walls forces.\u0026lt;br \/\u0026gt;\n\u0026amp;nbsp;\u0026lt;br \/\u0026gt;\n\u0026lt;strong\u0026gt;Learning Objectives\u0026lt;\/strong\u0026gt;\u0026lt;br \/\u0026gt;\n\u0026lt;br \/\u0026gt;\nIn this simulation, you will be able to:\u0026lt;br \/\u0026gt;\n\u0026amp;bull; explain the layered structure of graphite\u0026lt;br \/\u0026gt;\n\u0026amp;bull; describe the physical properties of graphite\u0026lt;br \/\u0026gt;\n\u0026amp;bull; recognize the hybridization of carbon atoms in graphite","BACKING_FILE":"ss200048.apk","FILE_UID":null,"SCORM_COURSE_ID":null,"CONT_SRC":"","MOD_FILES":null,"FOLDER_NAME":null,"CONTTYPE_ID":"9","ANDROID_PKG":"com.umety.vr.ss200048","TOPIC_ID":"ss200048","IS_PUBLISH":"Y","IS_PUBLIC":"Y","CONT_PRICE":null,"PUBLIC_IMG":"thumb_SS200048.jpg","PUBLIC_BANNER_IMG":"SS200048.jpg","PUBLIC_VIDEO":"pvideo_ss200048.mp4","PUBLIC_VIDEO_URL":"https:\/\/youtu.be\/gq2NqZsYfUs","DIST":null,"SHOW_ON_HOME":"N","CONTROLLER_REQUIRED":"Y","DOMAIN":"3","CONCEPT":"0","STATUS":"A","EXPIRY_DAYS":null,"CREATED_ON":"2018-01-19 07:16:38","CREATED_BY":"1","UPDATED_ON":"0000-00-00 00:00:00","UPDATED_BY":"2","CONT_ORDER":"0","X_ROTATION":null,"Y_ROTATION":null,"Z_ROTATION":null,"BG_COLOR":"0x000000","X_POSITION":null,"Y_POSITION":null,"Z_POSITION":null,"TEMP_DESC":"\u0026lt;div\u0026gt;Overview:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;Graphite is a crystalline allotrope of carbon. The crystalline structure of graphite consists of layers or sheets of carbon atoms. In these layers, each carbon atom is joined to three other carbon atoms by strong covalent bonds to form hexagonal rings. Various graphite layers are held together by weak Van der Waals forces.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;Learning Objectives:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;div\u0026gt;After completing this module, you will be able to:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Explain the layered structure of graphite.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Describe the physical properties of graphite.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Recognize the hybridization of carbon atoms in graphite.\u0026lt;\/div\u0026gt;\u0026lt;\/div\u0026gt;","IS_ANALYTICS":"Y","VR_ENABLE":"Y","VR_SESSION_ENABLE":"Y","YOUTUBE_URL":null,"CONT_TYPE":"VR Module","CAT_NAME":"Structure of graphite","ADMSUBJECT_ID":"820","ADMCOURSE_ID":"217","DISPLAY_NAME":"Cambridge - AS \u0026 A level - Chemistry","DISPLAY_NAME_AR":"Cambridge - AS \u0026 A level - Chemistry","SUBJECT_NAME":"Chemistry","SUBJECT_NAME_AR":"Chemistry","SUBJECT_DESC":"Chemistry","SUBJECT_DESC_AR":"Chemistry","SUBJECT_IMG":"","SUBJECT_BANNER_IMG":null,"SUBJECT_PRICE":null,"IS_FEATURED":"N","COURSE_NAME":"AS \u0026 A level","COUNTRY_ID":"296","SHORT_NAME":"Cambridge (IGCSE)","DOMAIN_NAME":"STEM"},{"CONT_ID":"247","CATEGORY_ID":"1","CONT_TITLE":"Allotropes of Carbon","CONT_SLUG":"allotropes-of-carbon","CONT_TITLE_AR":"Allotropes of Carbon","CONT_DESC":"\u003Ch3\u003EOverview:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EThe element carbon can exist in different physical forms called the allotropes of carbon. Three examples of carbon allotropes are: diamond, graphite, and buckyball. The physical properties of these allotropes are quite different due to the different arrangements of carbon atoms in their crystals.\u003C\/div\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Ch3\u003ELearning Objectives:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EAfter completing this module, you will be able to:\u003C\/div\u003E \r\n\u003Cdiv\u003E- Identify various allotropes of carbon.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Explain the different arrangements of the carbon atoms in diamond, graphite, and buckyball.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Compare the physical properties of diamond, graphite, and buckyball.\u003C\/div\u003E","CONT_DESC_AR":"The element carbon exists in three physical forms called the allotropes of carbon. Diamond, graphite and buckyball are the three allotropes of carbon. The physical properties of these allotropes are quite different due to the different arrangements of carbon atoms in their crystals.\u0026lt;br \/\u0026gt;\n\u0026amp;nbsp;\u0026lt;br \/\u0026gt;\n\u0026lt;strong\u0026gt;Learning Objectives\u0026lt;\/strong\u0026gt;\u0026lt;br \/\u0026gt;\n\u0026lt;br \/\u0026gt;\nIn this simulation, you will be able to:\u0026lt;br \/\u0026gt;\n\u0026amp;bull; identify the three allotropes of carbon\u0026lt;br \/\u0026gt;\n\u0026amp;bull; explain different arrangements of carbon atoms in diamond, graphite and buckyball\u0026lt;br \/\u0026gt;\n\u0026amp;bull; compare the physical properties of diamond, graphite and buckyball","BACKING_FILE":"ss200047.apk","FILE_UID":null,"SCORM_COURSE_ID":null,"CONT_SRC":"","MOD_FILES":null,"FOLDER_NAME":null,"CONTTYPE_ID":"9","ANDROID_PKG":"com.umety.vr.ss200047","TOPIC_ID":"ss200047","IS_PUBLISH":"Y","IS_PUBLIC":"Y","CONT_PRICE":null,"PUBLIC_IMG":"thumb_SS200047.jpg","PUBLIC_BANNER_IMG":"SS200047.jpg","PUBLIC_VIDEO":"pvideo_ss200047.mp4","PUBLIC_VIDEO_URL":"https:\/\/youtu.be\/EoiR4OnSF40","DIST":null,"SHOW_ON_HOME":"N","CONTROLLER_REQUIRED":"Y","DOMAIN":"3","CONCEPT":"0","STATUS":"A","EXPIRY_DAYS":null,"CREATED_ON":"2018-01-19 07:16:38","CREATED_BY":"1","UPDATED_ON":"0000-00-00 00:00:00","UPDATED_BY":"2","CONT_ORDER":"0","X_ROTATION":null,"Y_ROTATION":null,"Z_ROTATION":null,"BG_COLOR":"0x000000","X_POSITION":null,"Y_POSITION":null,"Z_POSITION":null,"TEMP_DESC":"\u0026lt;div\u0026gt;Overview:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;The element carbon can exist in different physical forms called the allotropes of carbon. Three examples of carbon allotropes are: diamond, graphite, and buckyball. The physical properties of these allotropes are quite different due to the different arrangements of carbon atoms in their crystals.\u0026amp;nbsp;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;Learning Objectives:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;div\u0026gt;After completing this module, you will be able to:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Identify various allotropes of carbon.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Explain the different arrangements of the carbon atoms in diamond, graphite, and buckyball.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Compare the physical properties of diamond, graphite, and buckyball.\u0026lt;\/div\u0026gt;\u0026lt;\/div\u0026gt;","IS_ANALYTICS":"Y","VR_ENABLE":"Y","VR_SESSION_ENABLE":"Y","YOUTUBE_URL":null,"CONT_TYPE":"VR Module","CAT_NAME":"Allotropes of carbon","ADMSUBJECT_ID":"820","ADMCOURSE_ID":"217","DISPLAY_NAME":"Cambridge - AS \u0026 A level - Chemistry","DISPLAY_NAME_AR":"Cambridge - AS \u0026 A level - Chemistry","SUBJECT_NAME":"Chemistry","SUBJECT_NAME_AR":"Chemistry","SUBJECT_DESC":"Chemistry","SUBJECT_DESC_AR":"Chemistry","SUBJECT_IMG":"","SUBJECT_BANNER_IMG":null,"SUBJECT_PRICE":null,"IS_FEATURED":"N","COURSE_NAME":"AS \u0026 A level","COUNTRY_ID":"296","SHORT_NAME":"Cambridge (IGCSE)","DOMAIN_NAME":"STEM"},{"CONT_ID":"246","CATEGORY_ID":"1","CONT_TITLE":"Alcohols","CONT_SLUG":"alcohols","CONT_TITLE_AR":"Alcohols","CONT_DESC":"\u003Ch3\u003EOverview:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E  \r\n\u003Cdiv\u003EAlcohols are the hydroxy derivatives of aliphatic hydrocarbons. In alcohols, the hydroxyl group is attached to an sp3-hybridized carbon atom. The electrostatic potential map of an alcohol molecule indicates that oxygen atoms of a hydroxy group provide a region of highest electron density due to the presence of lone pairs.\u003C\/div\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Ch3\u003ELearning Objectives:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EAfter completing this module, you will be able to:\u003C\/div\u003E \r\n\u003Cdiv\u003E- Identify the functional group present in alcohols.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Write the IUPAC name of an alcohol.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Explain the general formula of a homologous series of alcohols.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Predict the type of hybridization of carbon and oxygen atoms in an alcohol molecule.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Explain the charge distribution of a methanol molecule using an electrostatic potential map.\u003C\/div\u003E","CONT_DESC_AR":"Alcohols are the hydroxy derivatives of aliphatic hydrocarbons. In alcohols, the hydroxyl group is attached to an sp3-hybridised carbon atom. The electrostatic potential map of an alcohol molecule indicates that oxygen atoms of a hydroxy group provide a region of highest electron density due to the presence of lone pairs.\u0026lt;br \/\u0026gt;\n\u0026lt;br \/\u0026gt;\n\u0026lt;strong\u0026gt;Learning Objectives\u0026lt;\/strong\u0026gt;\u0026lt;br \/\u0026gt;\n\u0026lt;br \/\u0026gt;\nIn this simulation, you will be able to:\u0026lt;br \/\u0026gt;\n\u0026amp;bull; identify the functional group present in alcohols\u0026lt;br \/\u0026gt;\n\u0026amp;bull; write the IUPAC name of an alcohol\u0026lt;br \/\u0026gt;\n\u0026amp;bull; explain the general formula of a homologous series of alcohols\u0026lt;br \/\u0026gt;\n\u0026amp;bull; predict the type of hybridization of carbon and oxygen atoms in an alcohol molecule\u0026lt;br \/\u0026gt;\n\u0026amp;bull; explain the charge distribution of a methanol molecule using an electrostatic potential map","BACKING_FILE":"ss200055.apk","FILE_UID":null,"SCORM_COURSE_ID":null,"CONT_SRC":"","MOD_FILES":null,"FOLDER_NAME":null,"CONTTYPE_ID":"9","ANDROID_PKG":"com.umety.vr.ss200055","TOPIC_ID":"ss200055","IS_PUBLISH":"Y","IS_PUBLIC":"Y","CONT_PRICE":null,"PUBLIC_IMG":"thumb_SS200055.jpg","PUBLIC_BANNER_IMG":"ss200055.jpg","PUBLIC_VIDEO":"pvideo_ss200055.mp4","PUBLIC_VIDEO_URL":"https:\/\/youtu.be\/J-IuFLRYZjU","DIST":null,"SHOW_ON_HOME":"N","CONTROLLER_REQUIRED":"Y","DOMAIN":"3","CONCEPT":"0","STATUS":"A","EXPIRY_DAYS":null,"CREATED_ON":"2018-01-19 07:16:38","CREATED_BY":"1","UPDATED_ON":"0000-00-00 00:00:00","UPDATED_BY":"2","CONT_ORDER":"0","X_ROTATION":null,"Y_ROTATION":null,"Z_ROTATION":null,"BG_COLOR":"0x000000","X_POSITION":null,"Y_POSITION":null,"Z_POSITION":null,"TEMP_DESC":"\u0026lt;p\u0026gt;Overview:\u0026lt;\/p\u0026gt;\u0026lt;p\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/p\u0026gt;\u0026lt;p\u0026gt;Alcohols are the hydroxy derivatives of aliphatic hydrocarbons. In alcohols, the hydroxyl group is attached to an sp3-hybridized carbon atom. The electrostatic potential map of an alcohol molecule indicates that oxygen atoms of a hydroxy group provide a region of highest electron density due to the presence of lone pairs.\u0026amp;nbsp;\u0026lt;\/p\u0026gt;\u0026lt;p\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/p\u0026gt;\u0026lt;p\u0026gt;Learning Objectives:\u0026lt;\/p\u0026gt;\u0026lt;p\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/p\u0026gt;\u0026lt;p\u0026gt;After completing this module, you will be able to:\u0026lt;\/p\u0026gt;\u0026lt;p\u0026gt;- Identify the functional group present in alcohols.\u0026lt;\/p\u0026gt;\u0026lt;p\u0026gt;- Write the IUPAC name of an alcohol.\u0026lt;\/p\u0026gt;\u0026lt;p\u0026gt;- Explain the general formula of a homologous series of alcohols.\u0026lt;\/p\u0026gt;\u0026lt;p\u0026gt;- Predict the type of hybridization of carbon and oxygen atoms in an alcohol molecule.\u0026lt;\/p\u0026gt;\u0026lt;p\u0026gt;- Explain the charge distribution of a methanol molecule using an electrostatic potential map.\u0026lt;\/p\u0026gt;","IS_ANALYTICS":"Y","VR_ENABLE":"Y","VR_SESSION_ENABLE":"Y","YOUTUBE_URL":null,"CONT_TYPE":"VR Module","CAT_NAME":"Alcohols","ADMSUBJECT_ID":"820","ADMCOURSE_ID":"217","DISPLAY_NAME":"Cambridge - AS \u0026 A level - Chemistry","DISPLAY_NAME_AR":"Cambridge - AS \u0026 A level - Chemistry","SUBJECT_NAME":"Chemistry","SUBJECT_NAME_AR":"Chemistry","SUBJECT_DESC":"Chemistry","SUBJECT_DESC_AR":"Chemistry","SUBJECT_IMG":"","SUBJECT_BANNER_IMG":null,"SUBJECT_PRICE":null,"IS_FEATURED":"N","COURSE_NAME":"AS \u0026 A level","COUNTRY_ID":"296","SHORT_NAME":"Cambridge (IGCSE)","DOMAIN_NAME":"STEM"},{"CONT_ID":"242","CATEGORY_ID":"1","CONT_TITLE":"Titration of a Strong Acid with a Strong Base","CONT_SLUG":"titration-of-a-strong-acid-with-a-strong-base","CONT_TITLE_AR":"Titration of a Strong Acid with a Strong Base","CONT_DESC":"\u003Ch3\u003EOverview:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003ETitration of a strong acid with a strong base is used to determine the concentration of unknown acid by titrating it with a strong base of known concentration. Both the strong acid and the strong base are completely neutralized at an equivalence point, giving a pH of 7.\u003C\/div\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Ch3\u003ELearning Objectives:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EAfter completing this module, you will be able to:\u003C\/div\u003E \r\n\u003Cdiv\u003E- Describe the detailed procedure for the titration of a strong acid with a strong base.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Explain the laboratory setup for the titration of a strong acid with a strong base.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Describe the application of the titration of a strong acid with a strong base.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Extrapolate the graph for the titration of a strong acid with a strong base.\u003C\/div\u003E","CONT_DESC_AR":"Strong acid-strong base titration is used to determine the concentration of unknown acid by titrating it with a strong base of known concentration. Both the strong acid and the strong base are completely neutralized at an equivalence point, giving a pH of 7.\u0026lt;br \/\u0026gt;\n\u0026lt;br \/\u0026gt;\n\u0026lt;strong\u0026gt;Learning Objectives\u0026lt;\/strong\u0026gt;\u0026lt;br \/\u0026gt;\n\u0026lt;br \/\u0026gt;\nIn this simulation you will be able to:\u0026lt;br \/\u0026gt;\n\u0026amp;bull; describe the detailed procedure for the titration of a strong acid with a strong base\u0026lt;br \/\u0026gt;\n\u0026amp;bull; explain the laboratory setup for the titration of a strong acid with a strong base\u0026lt;br \/\u0026gt;\n\u0026amp;bull; describe the application of titration of a strong acid with a strong base\u0026lt;br \/\u0026gt;\n\u0026amp;bull; extrapolate the graph for the titration of a strong acid with a strong base","BACKING_FILE":"ss200032.apk","FILE_UID":null,"SCORM_COURSE_ID":null,"CONT_SRC":"","MOD_FILES":null,"FOLDER_NAME":null,"CONTTYPE_ID":"9","ANDROID_PKG":"com.umety.vr.ss200032","TOPIC_ID":"ss200032","IS_PUBLISH":"Y","IS_PUBLIC":"Y","CONT_PRICE":null,"PUBLIC_IMG":"thumb_SS200032.jpg","PUBLIC_BANNER_IMG":"SS200032.jpg","PUBLIC_VIDEO":"pvideo_ss200032.mp4","PUBLIC_VIDEO_URL":"https:\/\/youtu.be\/R4ghDnAEBuo","DIST":null,"SHOW_ON_HOME":"N","CONTROLLER_REQUIRED":"Y","DOMAIN":"3","CONCEPT":"0","STATUS":"A","EXPIRY_DAYS":null,"CREATED_ON":"2018-01-19 07:16:38","CREATED_BY":"1","UPDATED_ON":"0000-00-00 00:00:00","UPDATED_BY":"2","CONT_ORDER":"0","X_ROTATION":null,"Y_ROTATION":null,"Z_ROTATION":null,"BG_COLOR":"0x000000","X_POSITION":null,"Y_POSITION":null,"Z_POSITION":null,"TEMP_DESC":"\u0026lt;div\u0026gt;Overview:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;Titration of a strong acid with a strong base is used to determine the concentration of unknown acid by titrating it with a strong base of known concentration. Both the strong acid and the strong base are completely neutralized at an equivalence point, giving a pH of 7.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;Learning Objectives:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;div\u0026gt;After completing this module, you will be able to:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Describe the detailed procedure for the titration of a strong acid with a strong base.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Explain the laboratory setup for the titration of a strong acid with a strong base.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Describe the application of the titration of a strong acid with a strong base.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Extrapolate the graph for the titration of a strong acid with a strong base.\u0026lt;\/div\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;\/div\u0026gt;","IS_ANALYTICS":"Y","VR_ENABLE":"Y","VR_SESSION_ENABLE":"Y","YOUTUBE_URL":null,"CONT_TYPE":"VR Module","CAT_NAME":"Titration of a strong acid with a strong base","ADMSUBJECT_ID":"820","ADMCOURSE_ID":"217","DISPLAY_NAME":"Cambridge - AS \u0026 A level - Chemistry","DISPLAY_NAME_AR":"Cambridge - AS \u0026 A level - Chemistry","SUBJECT_NAME":"Chemistry","SUBJECT_NAME_AR":"Chemistry","SUBJECT_DESC":"Chemistry","SUBJECT_DESC_AR":"Chemistry","SUBJECT_IMG":"","SUBJECT_BANNER_IMG":null,"SUBJECT_PRICE":null,"IS_FEATURED":"N","COURSE_NAME":"AS \u0026 A level","COUNTRY_ID":"296","SHORT_NAME":"Cambridge (IGCSE)","DOMAIN_NAME":"STEM"},{"CONT_ID":"240","CATEGORY_ID":"1","CONT_TITLE":"Electrolytic Cell","CONT_SLUG":"electrolytic-cell","CONT_TITLE_AR":"Electrolytic Cell","CONT_DESC":"\u003Ch3\u003EOverview:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EThe apparatus in which electrolysis is carried out is called electrolytic cell. In electrolysis, electrical energy is used to carry out a chemical reaction.\u003C\/div\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Ch3\u003ELearning Objectives:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EAfter completing this module, you will be able to:\u003C\/div\u003E \r\n\u003Cdiv\u003E- Identify the components used to construct an electrolytic cell.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Describe the working principle of an electrolytic cell.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Explain the applications of electrolytic cells.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Construct an electrolytic cell.\u003C\/div\u003E","CONT_DESC_AR":"The apparatus in which electrolysis is carried out is called electrolytic cell. In electrolysis, electrical energy is used to carry out a chemical reaction.\u0026lt;br \/\u0026gt;\n\u0026lt;br \/\u0026gt;\n\u0026lt;strong\u0026gt;Learning Objectives\u0026lt;\/strong\u0026gt;\u0026lt;br \/\u0026gt;\n\u0026lt;br \/\u0026gt;\nIn this simulation, you will be able to:\u0026lt;br \/\u0026gt;\n\u0026amp;bull; identify the equipment used in an electrolytic cell\u0026lt;br \/\u0026gt;\n\u0026amp;bull; construct an electrolytic cell\u0026lt;br \/\u0026gt;\n\u0026amp;bull; describe the principle of electrolytic cell function\u0026lt;br \/\u0026gt;\n\u0026amp;bull; explain the applications of electrolytic cells","BACKING_FILE":"ss200023.apk","FILE_UID":null,"SCORM_COURSE_ID":null,"CONT_SRC":"","MOD_FILES":null,"FOLDER_NAME":null,"CONTTYPE_ID":"9","ANDROID_PKG":"com.umety.vr.ss200023","TOPIC_ID":"ss200023","IS_PUBLISH":"Y","IS_PUBLIC":"Y","CONT_PRICE":null,"PUBLIC_IMG":"thumb_SS200023.jpg","PUBLIC_BANNER_IMG":"SS200023.jpg","PUBLIC_VIDEO":"pvideo_ss200023.mp4","PUBLIC_VIDEO_URL":"https:\/\/youtu.be\/VbY5Y80n-NI","DIST":null,"SHOW_ON_HOME":"N","CONTROLLER_REQUIRED":"Y","DOMAIN":"3","CONCEPT":"0","STATUS":"A","EXPIRY_DAYS":null,"CREATED_ON":"2018-01-19 07:16:38","CREATED_BY":"1","UPDATED_ON":"0000-00-00 00:00:00","UPDATED_BY":"2","CONT_ORDER":"0","X_ROTATION":null,"Y_ROTATION":null,"Z_ROTATION":null,"BG_COLOR":"0x000000","X_POSITION":null,"Y_POSITION":null,"Z_POSITION":null,"TEMP_DESC":"\u0026lt;div\u0026gt;Overview:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;The apparatus in which electrolysis is carried out is called electrolytic cell. In electrolysis, electrical energy is used to carry out a chemical reaction.\u0026amp;nbsp;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;Learning Objectives:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;div\u0026gt;After completing this module, you will be able to:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Identify the components used to construct an electrolytic cell.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Describe the working principle of an electrolytic cell.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Explain the applications of electrolytic cells.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Construct an electrolytic cell.\u0026lt;\/div\u0026gt;\u0026lt;\/div\u0026gt;","IS_ANALYTICS":"Y","VR_ENABLE":"Y","VR_SESSION_ENABLE":"Y","YOUTUBE_URL":null,"CONT_TYPE":"VR Module","CAT_NAME":"Electrolytic Cell","ADMSUBJECT_ID":"820","ADMCOURSE_ID":"217","DISPLAY_NAME":"Cambridge - AS \u0026 A level - Chemistry","DISPLAY_NAME_AR":"Cambridge - AS \u0026 A level - Chemistry","SUBJECT_NAME":"Chemistry","SUBJECT_NAME_AR":"Chemistry","SUBJECT_DESC":"Chemistry","SUBJECT_DESC_AR":"Chemistry","SUBJECT_IMG":"","SUBJECT_BANNER_IMG":null,"SUBJECT_PRICE":null,"IS_FEATURED":"N","COURSE_NAME":"AS \u0026 A level","COUNTRY_ID":"296","SHORT_NAME":"Cambridge (IGCSE)","DOMAIN_NAME":"STEM"},{"CONT_ID":"234","CATEGORY_ID":"1","CONT_TITLE":"Calculating the Oxidation Number","CONT_SLUG":"calculating-oxidation-number","CONT_TITLE_AR":"Calculating Oxidation Number","CONT_DESC":"\u003Ch3\u003EOverview:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EFor calculating the oxidation number, we calculate the number of electrons lost, gained or shared by an element in a chemical species.\u003C\/div\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Ch3\u003ELearning Objectives:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EAfter completing this module, you will be able to:\u003C\/div\u003E \r\n\u003Cdiv\u003E- Define oxidation number.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Assign oxidation number to different elements in a chemical species.\u003C\/div\u003E","CONT_DESC_AR":"While calculating the oxidation number, we calculate the number of electrons lost, gained or shared by an element in a chemical species.\u003C\/br\u003E\u003C\/br\u003E\r\n\u003Cstrong\u003ELearning Objectives\u003C\/strong\u003E\u003C\/br\u003E\u003C\/br\u003E\r\nIn this simulation you will be able to:\u003C\/br\u003E\r\n\u2022 define oxidation number\u003C\/br\u003E\r\n\u2022 assign the oxidation number to different elements in a chemical species","BACKING_FILE":"ss200027.apk","FILE_UID":null,"SCORM_COURSE_ID":null,"CONT_SRC":"","MOD_FILES":null,"FOLDER_NAME":null,"CONTTYPE_ID":"9","ANDROID_PKG":"com.umety.vr.ss200027","TOPIC_ID":"ss200027","IS_PUBLISH":"Y","IS_PUBLIC":"Y","CONT_PRICE":null,"PUBLIC_IMG":"thumb_SS200027.jpg","PUBLIC_BANNER_IMG":"SS200027.jpg","PUBLIC_VIDEO":"pvideo_ss200027.mp4","PUBLIC_VIDEO_URL":"https:\/\/youtu.be\/Jf7BP10vSVM","DIST":null,"SHOW_ON_HOME":"N","CONTROLLER_REQUIRED":"Y","DOMAIN":"3","CONCEPT":"0","STATUS":"A","EXPIRY_DAYS":null,"CREATED_ON":"2018-01-19 07:16:38","CREATED_BY":"1","UPDATED_ON":"0000-00-00 00:00:00","UPDATED_BY":"2","CONT_ORDER":"0","X_ROTATION":null,"Y_ROTATION":null,"Z_ROTATION":null,"BG_COLOR":"0x000000","X_POSITION":null,"Y_POSITION":null,"Z_POSITION":null,"TEMP_DESC":"\u0026lt;div\u0026gt;Overview:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;For calculating the oxidation number, we calculate the number of electrons lost, gained or shared by an element in a chemical species.\u0026amp;nbsp;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;Learning Objectives:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;div\u0026gt;After completing this module, you will be able to:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Define oxidation number.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Assign oxidation number to different elements in a chemical species.\u0026lt;\/div\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;","IS_ANALYTICS":"Y","VR_ENABLE":"Y","VR_SESSION_ENABLE":"Y","YOUTUBE_URL":null,"CONT_TYPE":"VR Module","CAT_NAME":"Calculating Oxidation number","ADMSUBJECT_ID":"820","ADMCOURSE_ID":"217","DISPLAY_NAME":"Cambridge - AS \u0026 A level - Chemistry","DISPLAY_NAME_AR":"Cambridge - AS \u0026 A level - Chemistry","SUBJECT_NAME":"Chemistry","SUBJECT_NAME_AR":"Chemistry","SUBJECT_DESC":"Chemistry","SUBJECT_DESC_AR":"Chemistry","SUBJECT_IMG":"","SUBJECT_BANNER_IMG":null,"SUBJECT_PRICE":null,"IS_FEATURED":"N","COURSE_NAME":"AS \u0026 A level","COUNTRY_ID":"296","SHORT_NAME":"Cambridge (IGCSE)","DOMAIN_NAME":"STEM"},{"CONT_ID":"229","CATEGORY_ID":"1","CONT_TITLE":"Feasibility of a Galvanic Cell","CONT_SLUG":"feasibility-of-galvanic-cell","CONT_TITLE_AR":"Feasibility of Galvanic cell","CONT_DESC":"\u003Ch3\u003EOverview:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EFor a galvanic cell reaction to be feasible, the standard cell potential must be positive. We can determine the feasibility of a cell reaction by calculating the standard cell potential from standard electrode potential data.\u003C\/div\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Ch3\u003ELearning Objectives:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EAfter completing this module, you will be able to:\u003C\/div\u003E \r\n\u003Cdiv\u003E- Describe the relation between the standard cell potential and the feasibility of a cell reaction.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Identify the conditions where a galvanic cell reaction is feasible.\u003C\/div\u003E","CONT_DESC_AR":"For a Galvanic cell reaction to be feasible the standard cell potential must be positive. We can determine the feasibility of a cell reaction by calculating the standard cell potential from standard electrode potential data.\u0026lt;br \/\u0026gt;\n\u0026lt;br \/\u0026gt;\n\u0026lt;strong\u0026gt;Learning Objectives\u0026lt;\/strong\u0026gt;\u0026lt;br \/\u0026gt;\n\u0026lt;br \/\u0026gt;\nIn this simulation, you will be able to:\u0026lt;br \/\u0026gt;\n\u0026amp;bull; describe the relation between the standard cell potential and the feasibility of a cell reaction\u0026lt;br \/\u0026gt;\n\u0026amp;bull; identify the conditions where a galvanic cell reaction is feasible","BACKING_FILE":"ss200037.apk","FILE_UID":null,"SCORM_COURSE_ID":null,"CONT_SRC":"","MOD_FILES":null,"FOLDER_NAME":null,"CONTTYPE_ID":"9","ANDROID_PKG":"com.umety.vr.ss200037","TOPIC_ID":"ss200037","IS_PUBLISH":"Y","IS_PUBLIC":"Y","CONT_PRICE":null,"PUBLIC_IMG":"thumb_SS200037.jpg","PUBLIC_BANNER_IMG":"SS200037.jpg","PUBLIC_VIDEO":"pvideo_ss200037.mp4","PUBLIC_VIDEO_URL":"https:\/\/youtu.be\/peQvICwZjAA","DIST":null,"SHOW_ON_HOME":"N","CONTROLLER_REQUIRED":"Y","DOMAIN":"3","CONCEPT":"0","STATUS":"A","EXPIRY_DAYS":null,"CREATED_ON":"2018-01-19 07:16:38","CREATED_BY":"1","UPDATED_ON":"0000-00-00 00:00:00","UPDATED_BY":"2","CONT_ORDER":"0","X_ROTATION":null,"Y_ROTATION":null,"Z_ROTATION":null,"BG_COLOR":"0x000000","X_POSITION":null,"Y_POSITION":null,"Z_POSITION":null,"TEMP_DESC":"\u0026lt;div\u0026gt;Overview:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;For a galvanic cell reaction to be feasible, the standard cell potential must be positive. We can determine the feasibility of a cell reaction by calculating the standard cell potential from standard electrode potential data.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;Learning Objectives:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;div\u0026gt;After completing this module, you will be able to:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Describe the relation between the standard cell potential and the feasibility of a cell reaction.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Identify the conditions where a galvanic cell reaction is feasible.\u0026lt;\/div\u0026gt;\u0026lt;\/div\u0026gt;","IS_ANALYTICS":"Y","VR_ENABLE":"Y","VR_SESSION_ENABLE":"Y","YOUTUBE_URL":null,"CONT_TYPE":"VR Module","CAT_NAME":"Feasibility of Galvanic cell","ADMSUBJECT_ID":"820","ADMCOURSE_ID":"217","DISPLAY_NAME":"Cambridge - AS \u0026 A level - Chemistry","DISPLAY_NAME_AR":"Cambridge - AS \u0026 A level - Chemistry","SUBJECT_NAME":"Chemistry","SUBJECT_NAME_AR":"Chemistry","SUBJECT_DESC":"Chemistry","SUBJECT_DESC_AR":"Chemistry","SUBJECT_IMG":"","SUBJECT_BANNER_IMG":null,"SUBJECT_PRICE":null,"IS_FEATURED":"N","COURSE_NAME":"AS \u0026 A level","COUNTRY_ID":"296","SHORT_NAME":"Cambridge (IGCSE)","DOMAIN_NAME":"STEM"},{"CONT_ID":"227","CATEGORY_ID":"1","CONT_TITLE":"Galvanic Cell","CONT_SLUG":"galvanic-cell","CONT_TITLE_AR":"Galvanic Cell","CONT_DESC":"\u003Ch3\u003EOverview:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EA galvanic cell is an electrochemical cell that converts chemical energy into electrical energy. In a galvanic cell, the metal which is more reactive is taken as anode and the less reactive metal is taken as cathode. Electric batteries are examples of galvanic cells.\u003C\/div\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Ch3\u003ELearning Objectives:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EAfter completing this module, you will be able to:\u003C\/div\u003E \r\n\u003Cdiv\u003E- Identify the components used to construct a galvanic cell.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Construct a galvanic cell.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Describe how a galvanic cell functions.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Explain the importance of a salt bridge in a galvanic cell.\u003C\/div\u003E","CONT_DESC_AR":"A Galvanic cell is an electrochemical cell that converts chemical energy into electrical energy. In a Galvanic cell the more reactive metal is taken as anode and the less reactive metal is taken as cathode. Electric batteries are examples of Galvanic cells.\u0026lt;br \/\u0026gt;\n\u0026lt;br \/\u0026gt;\n\u0026lt;strong\u0026gt;Learning Objectives\u0026lt;\/strong\u0026gt;\u0026lt;br \/\u0026gt;\n\u0026lt;br \/\u0026gt;\nIn this simulation you will be able to:\u0026lt;br \/\u0026gt;\n\u0026amp;bull; identify the pieces of equipment used to construct a galvanic cell\u0026lt;br \/\u0026gt;\n\u0026amp;bull; construct a galvanic cell\u0026lt;br \/\u0026gt;\n\u0026amp;bull; describe how a galvanic cell functions\u0026lt;br \/\u0026gt;\n\u0026amp;bull; describe the importance of a salt bridge in a galvanic cell","BACKING_FILE":"ss200010.apk","FILE_UID":null,"SCORM_COURSE_ID":null,"CONT_SRC":"","MOD_FILES":null,"FOLDER_NAME":null,"CONTTYPE_ID":"9","ANDROID_PKG":"com.umety.vr.ss200010","TOPIC_ID":"ss200010","IS_PUBLISH":"Y","IS_PUBLIC":"Y","CONT_PRICE":null,"PUBLIC_IMG":"thumb_SS200010.jpg","PUBLIC_BANNER_IMG":"SS200010.jpg","PUBLIC_VIDEO":"pvideo_ss200010.mp4","PUBLIC_VIDEO_URL":"https:\/\/youtu.be\/xfKUW6Cwxn4","DIST":null,"SHOW_ON_HOME":"N","CONTROLLER_REQUIRED":"Y","DOMAIN":"3","CONCEPT":"0","STATUS":"A","EXPIRY_DAYS":null,"CREATED_ON":"2018-01-19 07:16:38","CREATED_BY":"1","UPDATED_ON":"0000-00-00 00:00:00","UPDATED_BY":"2","CONT_ORDER":"0","X_ROTATION":null,"Y_ROTATION":null,"Z_ROTATION":null,"BG_COLOR":"0x000000","X_POSITION":null,"Y_POSITION":null,"Z_POSITION":null,"TEMP_DESC":"\u0026lt;div\u0026gt;Overview:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;A galvanic cell is an electrochemical cell that converts chemical energy into electrical energy. In a galvanic cell, the metal which is more reactive is taken as anode and the less reactive metal is taken as cathode. Electric batteries are examples of galvanic cells.\u0026amp;nbsp;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;Learning Objectives:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;div\u0026gt;After completing this module, you will be able to:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Identify the components used to construct a galvanic cell.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Construct a galvanic cell.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Describe how a galvanic cell functions.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;-\u0026amp;nbsp;\u0026lt;span style=\u0026quot;color: rgb(0, 0, 0); font-family: Arial; white-space: pre-wrap;\u0026quot;\u0026gt;Explain the importance of a salt bridge in a galvanic cell\u0026lt;\/span\u0026gt;.\u0026lt;\/div\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;","IS_ANALYTICS":"Y","VR_ENABLE":"Y","VR_SESSION_ENABLE":"Y","YOUTUBE_URL":null,"CONT_TYPE":"VR Module","CAT_NAME":"Galvanic Cell","ADMSUBJECT_ID":"820","ADMCOURSE_ID":"217","DISPLAY_NAME":"Cambridge - AS \u0026 A level - Chemistry","DISPLAY_NAME_AR":"Cambridge - AS \u0026 A level - Chemistry","SUBJECT_NAME":"Chemistry","SUBJECT_NAME_AR":"Chemistry","SUBJECT_DESC":"Chemistry","SUBJECT_DESC_AR":"Chemistry","SUBJECT_IMG":"","SUBJECT_BANNER_IMG":null,"SUBJECT_PRICE":null,"IS_FEATURED":"N","COURSE_NAME":"AS \u0026 A level","COUNTRY_ID":"296","SHORT_NAME":"Cambridge (IGCSE)","DOMAIN_NAME":"STEM"},{"CONT_ID":"224","CATEGORY_ID":"1","CONT_TITLE":"Structure of Alkynes","CONT_SLUG":"structure-of-alkynes","CONT_TITLE_AR":"Structure of Alkynes","CONT_DESC":"\u003Ch3\u003EOverview:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EAlkynes are hydrocarbons that contain at least one carbon-carbon triple bond. Each carbon atoms in alkyne making a triple bond is sp hybridized. Hence alkynes contain both sigma and pi-bond. Ethyne is the simplest hydrocarbon, with chemical formula C2H2.\u003C\/div\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Ch3\u003ELearning Objectives:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EAfter completing this module, you will be able to:\u003C\/div\u003E \r\n\u003Cdiv\u003E- Identify an alkyne molecule.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Describe the structure and hybridization of the simplest alkyne molecule, ethyne.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Describe bonding and hybridization in alkynes.\u003C\/div\u003E","CONT_DESC_AR":"Alkynes are hydrocarbons that contain at least one carbon-carbon triple bond. Each carbon atoms in alkyne making a triple bond is sp hybridized. Hence alkynes contain both sigma and pi-bond. Ethyne is the simplest hydrocarbon, with chemical formulae C2H2.\u0026lt;br \/\u0026gt;\n\u0026lt;br \/\u0026gt;\n\u0026lt;strong\u0026gt;Learning Objectives\u0026lt;\/strong\u0026gt;\u0026lt;br \/\u0026gt;\n\u0026lt;br \/\u0026gt;\nIn this simulation, you will be able to:\u0026lt;br \/\u0026gt;\n\u0026amp;bull; identify an alkyne molecule\u0026lt;br \/\u0026gt;\n\u0026amp;bull; describe the structure and hybridisation of the simplest alkyne molecule, ethyne\u0026lt;br \/\u0026gt;\n\u0026amp;bull; describe bonding and hybridisation in alkynes","BACKING_FILE":"ss200009.apk","FILE_UID":null,"SCORM_COURSE_ID":null,"CONT_SRC":"","MOD_FILES":null,"FOLDER_NAME":null,"CONTTYPE_ID":"9","ANDROID_PKG":"com.umety.vr.ss200009","TOPIC_ID":"ss200009","IS_PUBLISH":"Y","IS_PUBLIC":"Y","CONT_PRICE":null,"PUBLIC_IMG":"thumb_SS200009.jpg","PUBLIC_BANNER_IMG":"SS200009.jpg","PUBLIC_VIDEO":"pvideo_ss200009.mp4","PUBLIC_VIDEO_URL":"https:\/\/youtu.be\/EGv4LSMdQwo","DIST":null,"SHOW_ON_HOME":"N","CONTROLLER_REQUIRED":"Y","DOMAIN":"3","CONCEPT":"0","STATUS":"A","EXPIRY_DAYS":null,"CREATED_ON":"2018-01-19 07:16:38","CREATED_BY":"1","UPDATED_ON":"0000-00-00 00:00:00","UPDATED_BY":"2","CONT_ORDER":"0","X_ROTATION":null,"Y_ROTATION":null,"Z_ROTATION":null,"BG_COLOR":"0x000000","X_POSITION":null,"Y_POSITION":null,"Z_POSITION":null,"TEMP_DESC":"\u0026lt;div\u0026gt;Overview:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;Alkynes are hydrocarbons that contain at least one carbon-carbon triple bond. Each carbon atoms in alkyne making a triple bond is sp hybridized. Hence alkynes contain both sigma and pi-bond. Ethyne is the simplest hydrocarbon, with chemical formula C2H2.\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;Learning Objectives:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;div\u0026gt;After completing this module, you will be able to:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Identify an alkyne molecule.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Describe the structure and hybridization of the simplest alkyne molecule, ethyne.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Describe bonding and hybridization in alkynes.\u0026lt;\/div\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;","IS_ANALYTICS":"Y","VR_ENABLE":"Y","VR_SESSION_ENABLE":"Y","YOUTUBE_URL":null,"CONT_TYPE":"VR Module","CAT_NAME":"Structure of alkynes","ADMSUBJECT_ID":"820","ADMCOURSE_ID":"217","DISPLAY_NAME":"Cambridge - AS \u0026 A level - Chemistry","DISPLAY_NAME_AR":"Cambridge - AS \u0026 A level - Chemistry","SUBJECT_NAME":"Chemistry","SUBJECT_NAME_AR":"Chemistry","SUBJECT_DESC":"Chemistry","SUBJECT_DESC_AR":"Chemistry","SUBJECT_IMG":"","SUBJECT_BANNER_IMG":null,"SUBJECT_PRICE":null,"IS_FEATURED":"N","COURSE_NAME":"AS \u0026 A level","COUNTRY_ID":"296","SHORT_NAME":"Cambridge (IGCSE)","DOMAIN_NAME":"STEM"},{"CONT_ID":"220","CATEGORY_ID":"1","CONT_TITLE":"Structure of Alkenes","CONT_SLUG":"structure-of-alkenes","CONT_TITLE_AR":"Structure of Alkenes","CONT_DESC":"\u003Ch3\u003EOverview:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EAlkenes are hydrocarbons that contain at least one carbon-carbon double bond. Each of the carbon atoms in alkene making a double bond is sp\u00b2 hybridized. Hence alkenes contain both sigma and pi-bond. Ethene is the simplest hydrocarbon, with a chemical formula of C2H4.\u003C\/div\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Ch3\u003ELearning Objectives:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EAfter completing this module, you will be able to:\u003C\/div\u003E \r\n\u003Cdiv\u003E- Identify an alkene molecule.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Describe the structure and hybridization of the simplest alkene molecule, ethene.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Describe bonding and hybridization in alkenes.\u003C\/div\u003E","CONT_DESC_AR":"Alkenes are hydrocarbons that contain at least one carbon-carbon double bond. Each of the carbon atoms in alkene making a double bond is sp2 hybridized. Hence alkenes contain both sigma and pi-bond. Ethene is the simplest hydrocarbon, with a chemical formula of C2H4.\u0026lt;br \/\u0026gt;\n\u0026lt;br \/\u0026gt;\n\u0026lt;strong\u0026gt;Learning Objectives\u0026lt;\/strong\u0026gt;\u0026lt;br \/\u0026gt;\n\u0026lt;br \/\u0026gt;\nIn this simulation you will be able to\u0026lt;br \/\u0026gt;\n\u0026amp;bull; identify an alkene molecule\u0026lt;br \/\u0026gt;\n\u0026amp;bull; describe the structure and hybridisation of the simplest alkene molecule, ethene\u0026lt;br \/\u0026gt;\n\u0026amp;bull; describe the bonding and hybridisation in alkenes","BACKING_FILE":"ss200005.apk","FILE_UID":null,"SCORM_COURSE_ID":null,"CONT_SRC":"","MOD_FILES":null,"FOLDER_NAME":null,"CONTTYPE_ID":"9","ANDROID_PKG":"com.umety.vr.ss200005","TOPIC_ID":"ss200005","IS_PUBLISH":"Y","IS_PUBLIC":"Y","CONT_PRICE":null,"PUBLIC_IMG":"thumb_SS200005.jpg","PUBLIC_BANNER_IMG":"SS200005.jpg","PUBLIC_VIDEO":"pvideo_ss200005.mp4","PUBLIC_VIDEO_URL":"https:\/\/youtu.be\/z4Tr-o6KRBs","DIST":null,"SHOW_ON_HOME":"N","CONTROLLER_REQUIRED":"Y","DOMAIN":"3","CONCEPT":"0","STATUS":"A","EXPIRY_DAYS":null,"CREATED_ON":"2018-01-19 07:16:38","CREATED_BY":"1","UPDATED_ON":"0000-00-00 00:00:00","UPDATED_BY":"2","CONT_ORDER":"0","X_ROTATION":null,"Y_ROTATION":null,"Z_ROTATION":null,"BG_COLOR":"0x000000","X_POSITION":null,"Y_POSITION":null,"Z_POSITION":null,"TEMP_DESC":"\u0026lt;p\u0026gt;Overview:\u0026lt;\/p\u0026gt;\u0026lt;p\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/p\u0026gt;\u0026lt;p\u0026gt;Alkenes are hydrocarbons that contain at least one carbon-carbon double bond. Each of the carbon atoms in alkene making a double bond is sp\u00b2 hybridized. Hence alkenes contain both sigma and pi-bond. Ethene is the simplest hydrocarbon, with a chemical formula of C2H4.\u0026amp;nbsp;\u0026lt;br\u0026gt;\u0026lt;\/p\u0026gt;\u0026lt;p\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/p\u0026gt;\u0026lt;p\u0026gt;Learning Objectives:\u0026lt;\/p\u0026gt;\u0026lt;p\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/p\u0026gt;\u0026lt;p\u0026gt;After completing this module, you will be able to:\u0026lt;\/p\u0026gt;\u0026lt;p\u0026gt;- Identify an alkene molecule.\u0026lt;\/p\u0026gt;\u0026lt;p\u0026gt;- Describe the structure and hybridization of the simplest alkene molecule, ethene.\u0026lt;\/p\u0026gt;\u0026lt;p\u0026gt;- Describe bonding and hybridization in alkenes.\u0026lt;\/p\u0026gt;","IS_ANALYTICS":"Y","VR_ENABLE":"Y","VR_SESSION_ENABLE":"Y","YOUTUBE_URL":null,"CONT_TYPE":"VR Module","CAT_NAME":"Structure of alkenes","ADMSUBJECT_ID":"820","ADMCOURSE_ID":"217","DISPLAY_NAME":"Cambridge - AS \u0026 A level - Chemistry","DISPLAY_NAME_AR":"Cambridge - AS \u0026 A level - Chemistry","SUBJECT_NAME":"Chemistry","SUBJECT_NAME_AR":"Chemistry","SUBJECT_DESC":"Chemistry","SUBJECT_DESC_AR":"Chemistry","SUBJECT_IMG":"","SUBJECT_BANNER_IMG":null,"SUBJECT_PRICE":null,"IS_FEATURED":"N","COURSE_NAME":"AS \u0026 A level","COUNTRY_ID":"296","SHORT_NAME":"Cambridge (IGCSE)","DOMAIN_NAME":"STEM"},{"CONT_ID":"217","CATEGORY_ID":"1","CONT_TITLE":"Structure of Alkanes","CONT_SLUG":"structure-of-alkanes","CONT_TITLE_AR":"Structure of Alkanes","CONT_DESC":"\u003Ch3\u003EOverview:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EAlkanes are hydrocarbons that contain only a single bond. All the carbon atoms in an alkane are sp3 hybridized. Hence only a sigma bond is found in alkanes. Methane is the simplest hydrocarbon with a chemical formula of CH4.\u003C\/div\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Ch3\u003ELearning Objectives:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EAfter completing this module, you will be able to:\u003C\/div\u003E \r\n\u003Cdiv\u003E- Identify alkane.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Explain the structure of an alkane.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Describe bonding and hybridization in alkanes.\u003C\/div\u003E","CONT_DESC_AR":"Alkanes are hydrocarbons that contain only a single bond. All the carbon atoms in an alkane are sp3 hybridized. Hence only a sigma bond is found in alkanes. Methane is the simplest hydrocarbon with a chemical formula of CH4.\u0026lt;br \/\u0026gt;\n\u0026lt;br \/\u0026gt;\n\u0026lt;strong\u0026gt;Learning Objectives\u0026lt;\/strong\u0026gt;\u0026lt;br \/\u0026gt;\n\u0026lt;br \/\u0026gt;\nIn this simulation, you will be able to:\u0026lt;br \/\u0026gt;\n\u0026amp;bull; identify an alkane\u0026lt;br \/\u0026gt;\n\u0026amp;bull; explain the structure of an alkane\u0026lt;br \/\u0026gt;\n\u0026amp;bull; describe the bonding and hybridisation in alkanes","BACKING_FILE":"ss200002.apk","FILE_UID":null,"SCORM_COURSE_ID":null,"CONT_SRC":"","MOD_FILES":null,"FOLDER_NAME":null,"CONTTYPE_ID":"9","ANDROID_PKG":"com.umety.vr.ss200002","TOPIC_ID":"ss200002","IS_PUBLISH":"Y","IS_PUBLIC":"Y","CONT_PRICE":null,"PUBLIC_IMG":"thumb_SS200002.jpg","PUBLIC_BANNER_IMG":"SS200002.jpg","PUBLIC_VIDEO":"pvideo_ss200002.mp4","PUBLIC_VIDEO_URL":"https:\/\/youtu.be\/PsksVs8o8hg","DIST":null,"SHOW_ON_HOME":"N","CONTROLLER_REQUIRED":"Y","DOMAIN":"3","CONCEPT":"0","STATUS":"A","EXPIRY_DAYS":null,"CREATED_ON":"2018-01-19 07:16:38","CREATED_BY":"1","UPDATED_ON":"0000-00-00 00:00:00","UPDATED_BY":"2","CONT_ORDER":"0","X_ROTATION":null,"Y_ROTATION":null,"Z_ROTATION":null,"BG_COLOR":"0x000000","X_POSITION":null,"Y_POSITION":null,"Z_POSITION":null,"TEMP_DESC":"\u0026lt;div\u0026gt;Overview:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;Alkanes are hydrocarbons that contain only a single bond. All the carbon atoms in an alkane are sp3 hybridized. Hence only a sigma bond is found in alkanes. Methane is the simplest hydrocarbon with a chemical formula of CH4.\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;Learning Objectives:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;div\u0026gt;After completing this module, you will be able to:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Identify alkane.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Explain the structure of an alkane.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Describe bonding and hybridization in alkanes.\u0026lt;\/div\u0026gt;\u0026lt;\/div\u0026gt;","IS_ANALYTICS":"Y","VR_ENABLE":"Y","VR_SESSION_ENABLE":"Y","YOUTUBE_URL":null,"CONT_TYPE":"VR Module","CAT_NAME":"Structure of alkanes","ADMSUBJECT_ID":"820","ADMCOURSE_ID":"217","DISPLAY_NAME":"Cambridge - AS \u0026 A level - Chemistry","DISPLAY_NAME_AR":"Cambridge - AS \u0026 A level - Chemistry","SUBJECT_NAME":"Chemistry","SUBJECT_NAME_AR":"Chemistry","SUBJECT_DESC":"Chemistry","SUBJECT_DESC_AR":"Chemistry","SUBJECT_IMG":"","SUBJECT_BANNER_IMG":null,"SUBJECT_PRICE":null,"IS_FEATURED":"N","COURSE_NAME":"AS \u0026 A level","COUNTRY_ID":"296","SHORT_NAME":"Cambridge (IGCSE)","DOMAIN_NAME":"STEM"},{"CONT_ID":"213","CATEGORY_ID":"1","CONT_TITLE":"Catalysts","CONT_SLUG":"catalysts","CONT_TITLE_AR":"Catalysts","CONT_DESC":"\u003Ch3\u003EOverview:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EA catalyst is a substance that increases the rate of a chemical reaction without itself undergoing any permanent chemical change. Enzymes are naturally occurring catalysts responsible for many essential biochemical reactions.\u003C\/div\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Ch3\u003ELearning Objectives:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EAfter completing this module, you will be able to:\u003C\/div\u003E \r\n\u003Cdiv\u003E- Define catalyst.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Explain the effect of a catalyst on the rate of a chemical reaction.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Explain how a catalyst increases the rate of a chemical reaction.\u003C\/div\u003E","CONT_DESC_AR":"A catalyst is a substance that increases the rate of a chemical reaction without itself undergoing any permanent chemical change. Enzymes are naturally occurring catalysts responsible for many essential biochemical reactions.\u0026lt;br \/\u0026gt;\n\u0026lt;br \/\u0026gt;\n\u0026lt;strong\u0026gt;Learning Objectives\u0026lt;\/strong\u0026gt;\u0026lt;br \/\u0026gt;\n\u0026lt;br \/\u0026gt;\nIn this simulation, you will be able to:\u0026lt;br \/\u0026gt;\n\u0026amp;bull; define catalyst\u0026lt;br \/\u0026gt;\n\u0026amp;bull; explain effect of catalyst on the rate of a chemical reaction\u0026lt;br \/\u0026gt;\n\u0026amp;bull; explain how a catalyst increases the rate of a chemical reaction","BACKING_FILE":null,"FILE_UID":null,"SCORM_COURSE_ID":null,"CONT_SRC":"","MOD_FILES":null,"FOLDER_NAME":null,"CONTTYPE_ID":"9","ANDROID_PKG":"com.umety.vr.ss200020","TOPIC_ID":"ss200020","IS_PUBLISH":"Y","IS_PUBLIC":"Y","CONT_PRICE":null,"PUBLIC_IMG":"thumb_SS200020.jpg","PUBLIC_BANNER_IMG":"ss200020.jpg","PUBLIC_VIDEO":"pvideo_ss200020.mp4","PUBLIC_VIDEO_URL":"https:\/\/youtu.be\/EpkHrhW2Xxc","DIST":null,"SHOW_ON_HOME":"N","CONTROLLER_REQUIRED":"Y","DOMAIN":"3","CONCEPT":"0","STATUS":"A","EXPIRY_DAYS":null,"CREATED_ON":"2018-01-19 07:16:38","CREATED_BY":"1","UPDATED_ON":"0000-00-00 00:00:00","UPDATED_BY":"2","CONT_ORDER":"0","X_ROTATION":null,"Y_ROTATION":null,"Z_ROTATION":null,"BG_COLOR":"0x000000","X_POSITION":null,"Y_POSITION":null,"Z_POSITION":null,"TEMP_DESC":"\u0026lt;div\u0026gt;Overview:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;A catalyst is a substance that increases the rate of a chemical reaction without itself undergoing any permanent chemical change. Enzymes are naturally occurring catalysts responsible for many essential biochemical reactions.\u0026amp;nbsp;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;Learning Objectives:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;div\u0026gt;After completing this module, you will be able to:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Define catalyst.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Explain the effect of a catalyst on the rate of a chemical reaction.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Explain how a catalyst increases the rate of a chemical reaction.\u0026lt;\/div\u0026gt;\u0026lt;\/div\u0026gt;","IS_ANALYTICS":"Y","VR_ENABLE":"Y","VR_SESSION_ENABLE":"Y","YOUTUBE_URL":null,"CONT_TYPE":"VR Module","CAT_NAME":"Catalysts","ADMSUBJECT_ID":"820","ADMCOURSE_ID":"217","DISPLAY_NAME":"Cambridge - AS \u0026 A level - Chemistry","DISPLAY_NAME_AR":"Cambridge - AS \u0026 A level - Chemistry","SUBJECT_NAME":"Chemistry","SUBJECT_NAME_AR":"Chemistry","SUBJECT_DESC":"Chemistry","SUBJECT_DESC_AR":"Chemistry","SUBJECT_IMG":"","SUBJECT_BANNER_IMG":null,"SUBJECT_PRICE":null,"IS_FEATURED":"N","COURSE_NAME":"AS \u0026 A level","COUNTRY_ID":"296","SHORT_NAME":"Cambridge (IGCSE)","DOMAIN_NAME":"STEM"},{"CONT_ID":"211","CATEGORY_ID":"1","CONT_TITLE":"Factors Affecting Equilibria","CONT_SLUG":"factors-affecting-equilibria","CONT_TITLE_AR":"Factors Affecting Equilibria","CONT_DESC":"\u003Ch3\u003EOverview:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EAccording to Le Chatelier\u2019s principle, if there is any change in the factors that affect the equilibrium condition of the system, the system will counteract or reduce the effect of the overall change. This principle is applicable to both physical as well as chemical equilibrium.\u003C\/div\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Ch3\u003ELearning Objectives:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EAfter completing this module, you will be able to:\u003C\/div\u003E \r\n\u003Cdiv\u003E- Explain that when there is any change in the factors that affect the equilibrium condition of the system, the system will counteract or reduce the effect of the overall change.\u003C\/div\u003E","CONT_DESC_AR":"According to Le Chateliers principle, if there is any change in the factors that affect the equilibrium condition of the system, the system will counteract or reduce the effect of the overall change. This principle is applicable to both physical as well as chemical equilibrium.\u0026lt;br \/\u0026gt;\n\u0026lt;br \/\u0026gt;\n\u0026lt;strong\u0026gt;Learning Objective\u0026lt;\/strong\u0026gt;\u0026lt;br \/\u0026gt;\n\u0026lt;br \/\u0026gt;\nIn this simulation, you will be able to:\u0026lt;br \/\u0026gt;\n\u0026amp;bull; explain, when there is any change in the factors that affect the equilibrium condition of the system, the system will counteract or reduce the effect of the overall change","BACKING_FILE":"ss200017.apk","FILE_UID":null,"SCORM_COURSE_ID":null,"CONT_SRC":"","MOD_FILES":null,"FOLDER_NAME":null,"CONTTYPE_ID":"9","ANDROID_PKG":"com.umety.vr.ss200017","TOPIC_ID":"ss200017","IS_PUBLISH":"Y","IS_PUBLIC":"Y","CONT_PRICE":null,"PUBLIC_IMG":"thumb_SS200017.jpg","PUBLIC_BANNER_IMG":"SS200017.jpg","PUBLIC_VIDEO":"pvideo_ss200017.mp4","PUBLIC_VIDEO_URL":"https:\/\/youtu.be\/KtndjzIHD3A","DIST":null,"SHOW_ON_HOME":"N","CONTROLLER_REQUIRED":"Y","DOMAIN":"3","CONCEPT":"0","STATUS":"A","EXPIRY_DAYS":null,"CREATED_ON":"2018-01-19 07:16:38","CREATED_BY":"1","UPDATED_ON":"0000-00-00 00:00:00","UPDATED_BY":"2","CONT_ORDER":"0","X_ROTATION":null,"Y_ROTATION":null,"Z_ROTATION":null,"BG_COLOR":"0x000000","X_POSITION":null,"Y_POSITION":null,"Z_POSITION":null,"TEMP_DESC":"\u0026lt;div\u0026gt;Overview:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;According to Le Chatelier\u2019s principle, if there is any change in the factors that affect the equilibrium condition of the system, the system will counteract or reduce the effect of the overall change. This principle is applicable to both physical as well as chemical equilibrium.\u0026amp;nbsp;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;Learning Objectives:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;div\u0026gt;After completing this module, you will be able to:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Explain that when there is any change in the factors that affect the equilibrium condition of the system, the system will counteract or reduce the effect of the overall change.\u0026lt;\/div\u0026gt;\u0026lt;\/div\u0026gt;","IS_ANALYTICS":"Y","VR_ENABLE":"Y","VR_SESSION_ENABLE":"Y","YOUTUBE_URL":null,"CONT_TYPE":"VR Module","CAT_NAME":"Factors affecting equilibria","ADMSUBJECT_ID":"820","ADMCOURSE_ID":"217","DISPLAY_NAME":"Cambridge - AS \u0026 A level - Chemistry","DISPLAY_NAME_AR":"Cambridge - AS \u0026 A level - Chemistry","SUBJECT_NAME":"Chemistry","SUBJECT_NAME_AR":"Chemistry","SUBJECT_DESC":"Chemistry","SUBJECT_DESC_AR":"Chemistry","SUBJECT_IMG":"","SUBJECT_BANNER_IMG":null,"SUBJECT_PRICE":null,"IS_FEATURED":"N","COURSE_NAME":"AS \u0026 A level","COUNTRY_ID":"296","SHORT_NAME":"Cambridge (IGCSE)","DOMAIN_NAME":"STEM"},{"CONT_ID":"200","CATEGORY_ID":"1","CONT_TITLE":"Structure of the Atom","CONT_SLUG":"structure-of-the-atom","CONT_TITLE_AR":"Structure of the Atom","CONT_DESC":"\u003Ch3\u003EOverview:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EEvery atom is made of a nucleus consisting of protons and neutrons. The nucleus is surrounded by electrons. Protons and electrons are oppositely charged, and neutrons have no charge. Thus the nucleus of an atom is positively charged.\u003C\/div\u003E \r\n\u003Cdiv\u003EOverall, an atom is electrically neutral because it has the same number of electrons as protons.\u003C\/div\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Ch3\u003ELearning Objectives:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EAfter completing this module, you will be able to:\u003C\/div\u003E \r\n\u003Cdiv\u003E- Identify the structure of an atom proposed by J. J. Thomson.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Identify the structure of an atom proposed by Rutherford.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Identify the structure of an atom proposed by Niels Bohr.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Identify the quantum mechanical model of an atom.\u003C\/div\u003E","CONT_DESC_AR":"In atoms, electrons which are found in the outermost shell are generally known as valence electrons and the number of valence electrons determines the valency of an atom.\u0026lt;br \/\u0026gt;\nThe valency of atoms of 1st, 2nd, 13th and 14th group elements are generally given as the number of valence electron.\u0026lt;br \/\u0026gt;\nAnd the valency of 15th to 18th group elements can be calculated by subtracting the number of valence electrons from the number eight.\u0026lt;br \/\u0026gt;\n\u0026lt;br \/\u0026gt;\n\u0026lt;strong\u0026gt;Learning Objectives\u0026lt;\/strong\u0026gt;\u0026lt;br \/\u0026gt;\n\u0026lt;br \/\u0026gt;\nIn this simulation, you will be able to:\u0026lt;br \/\u0026gt;\n\u0026amp;bull; identify the structure of an atom proposed by J. J. Thomson\u0026lt;br \/\u0026gt;\n\u0026amp;bull; identify the structure of an atom proposed by Rutherford\u0026lt;br \/\u0026gt;\n\u0026amp;bull; identify the structure of an atom proposed by Neils Bohr\u0026lt;br \/\u0026gt;\n\u0026amp;bull; identify the quantum mechanical model of an atom\u0026lt;br \/\u0026gt;\n\u0026amp;nbsp;","BACKING_FILE":"ss200006.apk","FILE_UID":null,"SCORM_COURSE_ID":null,"CONT_SRC":"","MOD_FILES":null,"FOLDER_NAME":null,"CONTTYPE_ID":"9","ANDROID_PKG":"com.umety.vr.ss200006","TOPIC_ID":"ss200006","IS_PUBLISH":"Y","IS_PUBLIC":"Y","CONT_PRICE":null,"PUBLIC_IMG":"thumb_SS200006.jpg","PUBLIC_BANNER_IMG":"SS200006.jpg","PUBLIC_VIDEO":"pvideo_ss200006.mp4","PUBLIC_VIDEO_URL":"https:\/\/youtu.be\/oGc6JdkYAwY","DIST":null,"SHOW_ON_HOME":"N","CONTROLLER_REQUIRED":"Y","DOMAIN":"3","CONCEPT":"0","STATUS":"A","EXPIRY_DAYS":null,"CREATED_ON":"2018-01-19 07:16:38","CREATED_BY":"1","UPDATED_ON":"0000-00-00 00:00:00","UPDATED_BY":"2","CONT_ORDER":"0","X_ROTATION":null,"Y_ROTATION":null,"Z_ROTATION":null,"BG_COLOR":"0x000000","X_POSITION":null,"Y_POSITION":null,"Z_POSITION":null,"TEMP_DESC":"\u0026lt;div\u0026gt;Overview:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;div\u0026gt;Every atom is made of a nucleus consisting of protons and neutrons. The nucleus is surrounded by electrons. Protons and electrons are oppositely charged, and neutrons have no charge. Thus the nucleus of an atom is positively charged.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;Overall, an atom is electrically neutral because it has the same number of electrons as protons.\u0026lt;\/div\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;Learning Objectives:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;div\u0026gt;After completing this module, you will be able to:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Identify the structure of an atom proposed by J. J. Thomson.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Identify the structure of an atom proposed by Rutherford.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Identify the structure of an atom proposed by Niels Bohr.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Identify the quantum mechanical model of an atom.\u0026lt;\/div\u0026gt;\u0026lt;\/div\u0026gt;","IS_ANALYTICS":"Y","VR_ENABLE":"Y","VR_SESSION_ENABLE":"Y","YOUTUBE_URL":null,"CONT_TYPE":"VR Module","CAT_NAME":"Structure of the Atom","ADMSUBJECT_ID":"820","ADMCOURSE_ID":"217","DISPLAY_NAME":"Cambridge - AS \u0026 A level - Chemistry","DISPLAY_NAME_AR":"Cambridge - AS \u0026 A level - Chemistry","SUBJECT_NAME":"Chemistry","SUBJECT_NAME_AR":"Chemistry","SUBJECT_DESC":"Chemistry","SUBJECT_DESC_AR":"Chemistry","SUBJECT_IMG":"","SUBJECT_BANNER_IMG":null,"SUBJECT_PRICE":null,"IS_FEATURED":"N","COURSE_NAME":"AS \u0026 A level","COUNTRY_ID":"296","SHORT_NAME":"Cambridge (IGCSE)","DOMAIN_NAME":"STEM"},{"CONT_ID":"192","CATEGORY_ID":"1","CONT_TITLE":"Structure of Methane","CONT_SLUG":"structure-of-methane","CONT_TITLE_AR":"Structure of Methane","CONT_DESC":"\u003Ch3\u003EOverview:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EA methane molecule contains one carbon and four hydrogen atoms. The four hydrogen atoms in methane molecule spread out evenly around the carbon atom, leading to the tetrahedral structure.\u003C\/div\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Ch3\u003ELearning Objectives:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EAfter completing this module, you will be able to:\u003C\/div\u003E \r\n\u003Cdiv\u003E- Write the molecular formula of methane.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Explain the hybridization of the carbon atom in methane.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Describe the tetrahedral structure of methane.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Calculate the number of covalent bonds present in methane.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Predict the C-H bond length and the H-C-H bond angle in methane.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Describe the electrostatic potential map of methane.\u003C\/div\u003E","CONT_DESC_AR":"A methane molecule contains one carbon and four hydrogen atoms. The four hydrogen atoms in methane molecule spread out evenly around the carbon atom, leading to the tetrahedral structure.\u0026lt;br \/\u0026gt;\n\u0026lt;br \/\u0026gt;\n\u0026lt;strong\u0026gt;Learning Objectives\u0026lt;\/strong\u0026gt;\u0026lt;br \/\u0026gt;\n\u0026lt;br \/\u0026gt;\nIn this simulation you will be able to:\u0026lt;br \/\u0026gt;\n\u0026amp;bull; write the molecular formula of methane\u0026lt;br \/\u0026gt;\n\u0026amp;bull; explain the hybridisation of the carbon atom in methane\u0026lt;br \/\u0026gt;\n\u0026amp;bull; describe the tetrahedral structure of methane\u0026lt;br \/\u0026gt;\n\u0026amp;bull; calculate the number of covalent bonds present in methane\u0026lt;br \/\u0026gt;\n\u0026amp;bull; predict the C-H bond length and the H-C-H bond angle in methane\u0026lt;br \/\u0026gt;\n\u0026amp;bull; describe the electrostatic potential map of methane","BACKING_FILE":"hs200078.apk","FILE_UID":null,"SCORM_COURSE_ID":null,"CONT_SRC":"","MOD_FILES":null,"FOLDER_NAME":null,"CONTTYPE_ID":"9","ANDROID_PKG":"com.umety.vr.hs200078","TOPIC_ID":"hs200078","IS_PUBLISH":"Y","IS_PUBLIC":"Y","CONT_PRICE":null,"PUBLIC_IMG":"thumb_HS200078.jpg","PUBLIC_BANNER_IMG":"HS200078.jpg","PUBLIC_VIDEO":"pvideo_hs200078.mp4","PUBLIC_VIDEO_URL":"https:\/\/youtu.be\/KyIxUUo8mzg","DIST":null,"SHOW_ON_HOME":"N","CONTROLLER_REQUIRED":"Y","DOMAIN":"3","CONCEPT":"0","STATUS":"A","EXPIRY_DAYS":null,"CREATED_ON":"2018-01-19 07:16:38","CREATED_BY":"1","UPDATED_ON":"0000-00-00 00:00:00","UPDATED_BY":"2","CONT_ORDER":"0","X_ROTATION":null,"Y_ROTATION":null,"Z_ROTATION":null,"BG_COLOR":"0x000000","X_POSITION":null,"Y_POSITION":null,"Z_POSITION":null,"TEMP_DESC":"\u0026lt;div\u0026gt;Overview:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;A methane molecule contains one carbon and four hydrogen atoms. The four hydrogen atoms in methane molecule spread out evenly around the carbon atom, leading to the tetrahedral structure.\u0026amp;nbsp;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;Learning Objectives:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;div\u0026gt;After completing this module, you will be able to:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Write the molecular formula of methane.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Explain the hybridization of the carbon atom in methane.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Describe the tetrahedral structure of methane.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Calculate the number of covalent bonds present in methane.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Predict the C-H bond length and the H-C-H bond angle in methane.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Describe the electrostatic potential map of methane.\u0026lt;\/div\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;","IS_ANALYTICS":"Y","VR_ENABLE":"Y","VR_SESSION_ENABLE":"Y","YOUTUBE_URL":null,"CONT_TYPE":"VR Module","CAT_NAME":"Structure of Methane","ADMSUBJECT_ID":"820","ADMCOURSE_ID":"217","DISPLAY_NAME":"Cambridge - AS \u0026 A level - Chemistry","DISPLAY_NAME_AR":"Cambridge - AS \u0026 A level - Chemistry","SUBJECT_NAME":"Chemistry","SUBJECT_NAME_AR":"Chemistry","SUBJECT_DESC":"Chemistry","SUBJECT_DESC_AR":"Chemistry","SUBJECT_IMG":"","SUBJECT_BANNER_IMG":null,"SUBJECT_PRICE":null,"IS_FEATURED":"N","COURSE_NAME":"AS \u0026 A level","COUNTRY_ID":"296","SHORT_NAME":"Cambridge (IGCSE)","DOMAIN_NAME":"STEM"},{"CONT_ID":"188","CATEGORY_ID":"1","CONT_TITLE":" Acids","CONT_SLUG":"acids","CONT_TITLE_AR":"The Acid","CONT_DESC":"\u003Ch3\u003EOverview:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EAn acid is a chemical species that donates protons or hydrogen ions and\/or accepts electrons. Acids are usually sour in taste.\u003C\/div\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Ch3\u003ELearning objective:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EAfter completing this module, you will be able to: \u003C\/div\u003E \r\n\u003Cdiv\u003E- Define acids. \u003C\/div\u003E \r\n\u003Cdiv\u003E- List some common acids. \u003C\/div\u003E \r\n\u003Cdiv\u003E- Identify the properties of acids.\u003C\/div\u003E","CONT_DESC_AR":"An acid is a compound that gives hydronium ions on ionisation. Acids are usually sour in taste.\u0026lt;br \/\u0026gt;\n\u0026lt;br \/\u0026gt;\n\u0026lt;strong\u0026gt;Learning Objectives\u0026lt;\/strong\u0026gt;\u0026lt;br \/\u0026gt;\n\u0026lt;br \/\u0026gt;\nIn this simulation, you will be able to:\u0026lt;br \/\u0026gt;\n\u0026amp;bull; define acids\u0026lt;br \/\u0026gt;\n\u0026amp;bull; list some common acids\u0026lt;br \/\u0026gt;\n\u0026amp;bull; identify the properties of acids","BACKING_FILE":"hs200059.apk","FILE_UID":null,"SCORM_COURSE_ID":null,"CONT_SRC":"","MOD_FILES":null,"FOLDER_NAME":null,"CONTTYPE_ID":"9","ANDROID_PKG":"com.umety.vr.hs200059","TOPIC_ID":"hs200059","IS_PUBLISH":"Y","IS_PUBLIC":"Y","CONT_PRICE":null,"PUBLIC_IMG":"thumb_HS200059.jpg","PUBLIC_BANNER_IMG":"HS200059.jpg","PUBLIC_VIDEO":"pvideo_hs200059.mp4","PUBLIC_VIDEO_URL":"https:\/\/youtu.be\/1DN17OR4aBk","DIST":null,"SHOW_ON_HOME":"N","CONTROLLER_REQUIRED":"Y","DOMAIN":"3","CONCEPT":"0","STATUS":"A","EXPIRY_DAYS":null,"CREATED_ON":"2018-01-19 07:16:38","CREATED_BY":"1","UPDATED_ON":"0000-00-00 00:00:00","UPDATED_BY":"2","CONT_ORDER":"0","X_ROTATION":null,"Y_ROTATION":null,"Z_ROTATION":null,"BG_COLOR":"0x000000","X_POSITION":null,"Y_POSITION":null,"Z_POSITION":null,"TEMP_DESC":"Overview:\u0026lt;br\u0026gt;\u0026lt;br\u0026gt;An acid is a chemical species that donates protons or hydrogen ions and\/or accepts electrons. Acids are usually sour in taste.\u0026lt;br\u0026gt;\u0026lt;br\u0026gt;Learning objective\u0026lt;br\u0026gt;\u0026lt;br\u0026gt;After completing this module, you will be able to:\u0026lt;br\u0026gt;\u0026amp;nbsp;- Define acids.\u0026lt;br\u0026gt;\u0026amp;nbsp;- List some common acids.\u0026lt;br\u0026gt;\u0026amp;nbsp;- Identify the properties of acids.\u0026lt;br\u0026gt;","IS_ANALYTICS":"Y","VR_ENABLE":"Y","VR_SESSION_ENABLE":"Y","YOUTUBE_URL":null,"CONT_TYPE":"VR Module","CAT_NAME":"Acids","ADMSUBJECT_ID":"820","ADMCOURSE_ID":"217","DISPLAY_NAME":"Cambridge - AS \u0026 A level - Chemistry","DISPLAY_NAME_AR":"Cambridge - AS \u0026 A level - Chemistry","SUBJECT_NAME":"Chemistry","SUBJECT_NAME_AR":"Chemistry","SUBJECT_DESC":"Chemistry","SUBJECT_DESC_AR":"Chemistry","SUBJECT_IMG":"","SUBJECT_BANNER_IMG":null,"SUBJECT_PRICE":null,"IS_FEATURED":"N","COURSE_NAME":"AS \u0026 A level","COUNTRY_ID":"296","SHORT_NAME":"Cambridge (IGCSE)","DOMAIN_NAME":"STEM"},{"CONT_ID":"181","CATEGORY_ID":"1","CONT_TITLE":"Rutherford\u0027s Atomic Model","CONT_SLUG":"rutherfords-atomic-model","CONT_TITLE_AR":"Rutherford\u2019s Atomic model","CONT_DESC":"\u003Ch3\u003EOverview:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EAccording to Rutherford\u2019s atomic model, the atom consists of two parts. First is the nucleus which is very small in size and carries a positive charge, and in which the entire mass of the atom is concentrated. The second part is the extra nuclear part, in which negatively charged electrons revolve around the nucleus on fixed circular paths.\u003C\/div\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Ch3\u003ELearning Objectives:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EAfter completing this module, you will be able to:\u003C\/div\u003E \r\n\u003Cdiv\u003E- Describe the structure of an atom according to Rutherford\u0026#039;s atomic model.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Identify Rutherford\u0026#039;s model of an atom.\u003C\/div\u003E","CONT_DESC_AR":"According to Rutherfords atomic model, the atom consists of two parts\u003Cbr\u003E\n1. Nucleus, very small in size, carries a positive charge and in which the entire mass of the atom is concentrated\u0026lt;br \/\u0026gt;\n2. Extra nuclear part, in which negatively charged electrons revolve around the nucleus on fixed circular paths\u0026lt;br \/\u0026gt;\n\u0026lt;br \/\u0026gt;\n\u0026lt;strong\u0026gt;Learning Objectives\u0026lt;\/strong\u0026gt;\u0026lt;br \/\u0026gt;\n\u0026lt;br \/\u0026gt;\nAt the end of simulation you will be able to:\u0026lt;br \/\u0026gt;\n\u0026amp;bull; describe the structure of an atom according\u0026lt;br \/\u0026gt;\n\u0026amp;nbsp;to Rutherford\u0026amp;#39;s atomic model\u0026lt;br \/\u0026gt;\n\u0026amp;bull; identify Rutherford\u0026amp;#39;s model of atom\u0026lt;br \/\u0026gt;\n\u0026amp;nbsp;","BACKING_FILE":"hs200040.apk","FILE_UID":null,"SCORM_COURSE_ID":null,"CONT_SRC":"","MOD_FILES":null,"FOLDER_NAME":null,"CONTTYPE_ID":"9","ANDROID_PKG":"com.umety.vr.hs200040","TOPIC_ID":"hs200040","IS_PUBLISH":"Y","IS_PUBLIC":"Y","CONT_PRICE":null,"PUBLIC_IMG":"thumb_HS200040.jpg","PUBLIC_BANNER_IMG":"HS200040.jpg","PUBLIC_VIDEO":"pvideo_hs200040.mp4","PUBLIC_VIDEO_URL":"https:\/\/youtu.be\/YyEDbnJd0lc","DIST":null,"SHOW_ON_HOME":"N","CONTROLLER_REQUIRED":"Y","DOMAIN":"3","CONCEPT":"0","STATUS":"A","EXPIRY_DAYS":null,"CREATED_ON":"2018-01-19 07:16:38","CREATED_BY":"1","UPDATED_ON":"0000-00-00 00:00:00","UPDATED_BY":"2","CONT_ORDER":"0","X_ROTATION":null,"Y_ROTATION":null,"Z_ROTATION":null,"BG_COLOR":"0x000000","X_POSITION":null,"Y_POSITION":null,"Z_POSITION":null,"TEMP_DESC":"\u0026lt;div\u0026gt;Overview:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;According to Rutherford\u2019s atomic model, the atom consists of two parts. First is the nucleus which is very small in size and\u0026amp;nbsp; carries a positive charge, and in which the entire mass of the atom is concentrated. The second part is the extra nuclear part, in which negatively charged electrons revolve around the nucleus on fixed circular paths.\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;Learning Objectives:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;div\u0026gt;After completing this module, you will be able to:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Describe the structure of an atom according\u0026amp;nbsp; to Rutherford\u0026#039;s atomic model.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Identify Rutherford\u0026#039;s model of an atom.\u0026lt;\/div\u0026gt;\u0026lt;\/div\u0026gt;","IS_ANALYTICS":"Y","VR_ENABLE":"Y","VR_SESSION_ENABLE":"Y","YOUTUBE_URL":null,"CONT_TYPE":"VR Module","CAT_NAME":"Rutherford\u2019s Atomic model","ADMSUBJECT_ID":"820","ADMCOURSE_ID":"217","DISPLAY_NAME":"Cambridge - AS \u0026 A level - Chemistry","DISPLAY_NAME_AR":"Cambridge - AS \u0026 A level - Chemistry","SUBJECT_NAME":"Chemistry","SUBJECT_NAME_AR":"Chemistry","SUBJECT_DESC":"Chemistry","SUBJECT_DESC_AR":"Chemistry","SUBJECT_IMG":"","SUBJECT_BANNER_IMG":null,"SUBJECT_PRICE":null,"IS_FEATURED":"N","COURSE_NAME":"AS \u0026 A level","COUNTRY_ID":"296","SHORT_NAME":"Cambridge (IGCSE)","DOMAIN_NAME":"STEM"},{"CONT_ID":"178","CATEGORY_ID":"1","CONT_TITLE":"Structure of Ethanal","CONT_SLUG":"structure-of-ethanal","CONT_TITLE_AR":"Structure of Ethanal","CONT_DESC":"\u003Ch3\u003EOverview:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EEthanal is commonly known as acetaldehyde. It is an aldehyde molecule containing two carbon atoms. Ethanal has five single bonds and one carbon-oxygen double bond.\u003C\/div\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Ch3\u003ELearning Objectives:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EAfter completing this module, you will be able to:\u003C\/div\u003E \r\n\u003Cdiv\u003E- Explain the structure of ethanal.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Identify the functional group present in ethanal.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Explain the types of covalent bonds present in ethanal.\u003C\/div\u003E","CONT_DESC_AR":"Ethanal is commonly known as acetaldehyde. It is an aldehyde molecule containing two carbon atoms. Ethanal has five single bonds and one carbon-oxygen double bond.\u0026lt;br \/\u0026gt;\n\u0026amp;nbsp;\u0026lt;br \/\u0026gt;\n\u0026lt;strong\u0026gt;Learning Objectives\u0026lt;\/strong\u0026gt;\u0026lt;br \/\u0026gt;\n\u0026lt;br \/\u0026gt;\nIn this simulation , you will be able to:\u0026lt;br \/\u0026gt;\n\u0026amp;bull; explain the structure of ethanal\u0026lt;br \/\u0026gt;\n\u0026amp;bull; identify the functional group present in ethanal\u0026lt;br \/\u0026gt;\n\u0026amp;bull; compare the molecular formula, structural formula, bond-line formula, and ball and stick model","BACKING_FILE":"hs200038.apk","FILE_UID":null,"SCORM_COURSE_ID":null,"CONT_SRC":"","MOD_FILES":null,"FOLDER_NAME":null,"CONTTYPE_ID":"9","ANDROID_PKG":"com.umety.vr.hs200038","TOPIC_ID":"hs200038","IS_PUBLISH":"Y","IS_PUBLIC":"Y","CONT_PRICE":null,"PUBLIC_IMG":"thumb_HS200038.jpg","PUBLIC_BANNER_IMG":"HS200038.jpg","PUBLIC_VIDEO":"pvideo_hs200038.mp4","PUBLIC_VIDEO_URL":"https:\/\/youtu.be\/OCIqGn4fCMc","DIST":null,"SHOW_ON_HOME":"N","CONTROLLER_REQUIRED":"Y","DOMAIN":"3","CONCEPT":"0","STATUS":"A","EXPIRY_DAYS":null,"CREATED_ON":"2018-01-19 07:16:38","CREATED_BY":"1","UPDATED_ON":"0000-00-00 00:00:00","UPDATED_BY":"2","CONT_ORDER":"0","X_ROTATION":null,"Y_ROTATION":null,"Z_ROTATION":null,"BG_COLOR":"0x000000","X_POSITION":null,"Y_POSITION":null,"Z_POSITION":null,"TEMP_DESC":"\u0026lt;div\u0026gt;Overview:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;Ethanal is commonly known as acetaldehyde. It is an aldehyde molecule containing two carbon atoms. Ethanal has five single bonds and one carbon-oxygen double bond.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;Learning Objectives:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;div\u0026gt;After completing this module, you will be able to:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Explain the structure of ethanal.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Identify the functional group present in ethanal.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Explain the types of covalent bonds present in ethanal.\u0026lt;\/div\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;","IS_ANALYTICS":"Y","VR_ENABLE":"Y","VR_SESSION_ENABLE":"Y","YOUTUBE_URL":null,"CONT_TYPE":"VR Module","CAT_NAME":"Structure of Ethanal","ADMSUBJECT_ID":"820","ADMCOURSE_ID":"217","DISPLAY_NAME":"Cambridge - AS \u0026 A level - Chemistry","DISPLAY_NAME_AR":"Cambridge - AS \u0026 A level - Chemistry","SUBJECT_NAME":"Chemistry","SUBJECT_NAME_AR":"Chemistry","SUBJECT_DESC":"Chemistry","SUBJECT_DESC_AR":"Chemistry","SUBJECT_IMG":"","SUBJECT_BANNER_IMG":null,"SUBJECT_PRICE":null,"IS_FEATURED":"N","COURSE_NAME":"AS \u0026 A level","COUNTRY_ID":"296","SHORT_NAME":"Cambridge (IGCSE)","DOMAIN_NAME":"STEM"},{"CONT_ID":"175","CATEGORY_ID":"1","CONT_TITLE":"Structure of Ethanol","CONT_SLUG":"structure-of-ethanol","CONT_TITLE_AR":"Structure of Ethanol","CONT_DESC":"\u003Ch3\u003EOverview:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EEthanol is commonly known as ethyl alcohol. It is an alcohol molecule containing the hydoxy functional group. An ethanol molecule has eight single bonds.\u003C\/div\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Ch3\u003ELearning Objectives:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EAfter completing this module, you will be able to:\u003C\/div\u003E \r\n\u003Cdiv\u003E- Identify functional groups present in ethanol.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Explain types of covalent bonds present in ethanol.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Predict the type of hybridization of carbon and oxygen atoms in ethanol molecule.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Explain charge distribution of an ethanol molecule using its electrostatic potential map.\u003C\/div\u003E","CONT_DESC_AR":"Ethanol is commonly known as ethyl alcohol. It is an alcohol molecule containing the hydoxy functional group. An ethanol molecule has eight single bonds.\u0026lt;br \/\u0026gt;\n\u0026amp;nbsp;\u0026lt;br \/\u0026gt;\n\u0026lt;strong\u0026gt;Learning Objectives\u0026lt;\/strong\u0026gt;\u0026lt;br \/\u0026gt;\n\u0026lt;br \/\u0026gt;\nIn this simulation , you will be able to:\u0026lt;br \/\u0026gt;\n\u0026amp;bull; identify functional groups present in ethanol\u0026lt;br \/\u0026gt;\n\u0026amp;bull; explain types of covalent bonds present in ethanol\u0026lt;br \/\u0026gt;\n\u0026amp;bull; predict the type of hybridization of carbon and oxygen atoms in an ethanol molecule\u0026lt;br \/\u0026gt;\n\u0026amp;bull; explain charge distribution of an ethanol molecule using its electrostatic potential map","BACKING_FILE":"hs200074.apk","FILE_UID":null,"SCORM_COURSE_ID":null,"CONT_SRC":"","MOD_FILES":null,"FOLDER_NAME":null,"CONTTYPE_ID":"9","ANDROID_PKG":"com.umety.vr.hs200074","TOPIC_ID":"hs200074","IS_PUBLISH":"Y","IS_PUBLIC":"Y","CONT_PRICE":null,"PUBLIC_IMG":"thumb_HS200074.jpg","PUBLIC_BANNER_IMG":"HS200074.jpg","PUBLIC_VIDEO":"pvideo_hs200074.mp4","PUBLIC_VIDEO_URL":"https:\/\/youtu.be\/NdG5hheY5ok","DIST":null,"SHOW_ON_HOME":"N","CONTROLLER_REQUIRED":"Y","DOMAIN":"3","CONCEPT":"0","STATUS":"A","EXPIRY_DAYS":null,"CREATED_ON":"2018-01-19 07:16:38","CREATED_BY":"1","UPDATED_ON":"0000-00-00 00:00:00","UPDATED_BY":"2","CONT_ORDER":"0","X_ROTATION":null,"Y_ROTATION":null,"Z_ROTATION":null,"BG_COLOR":"0x000000","X_POSITION":null,"Y_POSITION":null,"Z_POSITION":null,"TEMP_DESC":"\u0026lt;div\u0026gt;Overview:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;Ethanol is commonly known as ethyl alcohol. It is an alcohol molecule containing the hydoxy functional group. An ethanol molecule has eight single bonds.\u0026amp;nbsp;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;Learning Objectives:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;div\u0026gt;After completing this module, you will be able to:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Identify functional groups present in ethanol.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Explain types of covalent bonds present in ethanol.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Predict the type of hybridization of carbon and oxygen atoms in ethanol molecule.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Explain charge distribution of an ethanol molecule using its electrostatic potential map.\u0026lt;\/div\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;","IS_ANALYTICS":"Y","VR_ENABLE":"Y","VR_SESSION_ENABLE":"Y","YOUTUBE_URL":null,"CONT_TYPE":"VR Module","CAT_NAME":"Structure of Ethanol","ADMSUBJECT_ID":"820","ADMCOURSE_ID":"217","DISPLAY_NAME":"Cambridge - AS \u0026 A level - Chemistry","DISPLAY_NAME_AR":"Cambridge - AS \u0026 A level - Chemistry","SUBJECT_NAME":"Chemistry","SUBJECT_NAME_AR":"Chemistry","SUBJECT_DESC":"Chemistry","SUBJECT_DESC_AR":"Chemistry","SUBJECT_IMG":"","SUBJECT_BANNER_IMG":null,"SUBJECT_PRICE":null,"IS_FEATURED":"N","COURSE_NAME":"AS \u0026 A level","COUNTRY_ID":"296","SHORT_NAME":"Cambridge (IGCSE)","DOMAIN_NAME":"STEM"},{"CONT_ID":"173","CATEGORY_ID":"1","CONT_TITLE":"Valence Electrons","CONT_SLUG":"valence-electrons","CONT_TITLE_AR":"Valence Electrons","CONT_DESC":"\u003Ch3\u003EOverview:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EValence electrons are the electrons present in the outermost shell of an atom. Since they are involved in the formation of a molecule, they decide the valency of the atom.\u003C\/div\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Ch3\u003ELearning Objectives:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EAfter completing this module, you will be able to:\u003C\/div\u003E \r\n\u003Cdiv\u003E- Identify the outermost shell of an atom.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Count the number of valence electrons present in an atom.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Predict the number of valence electrons in the atoms of groups 1, 2, and 13 to 18 using the periodic table.\u003C\/div\u003E","CONT_DESC_AR":"Valence electrons are the electrons present in the outermost shell of an atom. The number of valence electrons in the atoms of groups 1,2 and 13 to 18 equals the ones digit of the group members.\u0026lt;br \/\u0026gt;\n\u0026lt;br \/\u0026gt;\n\u0026lt;strong\u0026gt;Learning Objectives\u0026lt;\/strong\u0026gt;\u0026lt;br \/\u0026gt;\n\u0026lt;br \/\u0026gt;\nIn this simulation , you will be able to:\u0026lt;br \/\u0026gt;\n- identify outermost shell of an atom\u0026amp;nbsp;\u0026lt;br \/\u0026gt;\n- count valence electrons present in an atom\u0026amp;nbsp;\u0026lt;br \/\u0026gt;\n- predict the number of valence electrons in the atoms of groups 1, 2 and 13 to 18 using periodic table\u0026lt;br \/\u0026gt;\n\u0026amp;nbsp;","BACKING_FILE":"hs200070.apk","FILE_UID":null,"SCORM_COURSE_ID":null,"CONT_SRC":"","MOD_FILES":null,"FOLDER_NAME":null,"CONTTYPE_ID":"9","ANDROID_PKG":"com.umety.vr.hs200070","TOPIC_ID":"hs200070","IS_PUBLISH":"Y","IS_PUBLIC":"Y","CONT_PRICE":null,"PUBLIC_IMG":"thumb_HS200070.jpg","PUBLIC_BANNER_IMG":"HS200070.jpg","PUBLIC_VIDEO":"pvideo_hs200070.mp4","PUBLIC_VIDEO_URL":"https:\/\/youtu.be\/ksLodK-mJ8c","DIST":null,"SHOW_ON_HOME":"N","CONTROLLER_REQUIRED":"Y","DOMAIN":"3","CONCEPT":"0","STATUS":"A","EXPIRY_DAYS":null,"CREATED_ON":"2018-01-19 07:16:38","CREATED_BY":"1","UPDATED_ON":"0000-00-00 00:00:00","UPDATED_BY":"2","CONT_ORDER":"0","X_ROTATION":null,"Y_ROTATION":null,"Z_ROTATION":null,"BG_COLOR":"0x000000","X_POSITION":null,"Y_POSITION":null,"Z_POSITION":null,"TEMP_DESC":"Overview:\u0026lt;br\u0026gt;\u0026lt;br\u0026gt;Valence electrons are the electrons present in the outermost shell of an atom. Since they are involved in the formation of a molecule, they decide the valency of the atom.\u0026lt;br\u0026gt;\u0026lt;br\u0026gt;Learning objectives\u0026lt;br\u0026gt;\u0026lt;br\u0026gt;After completing this module, you will be able to:\u0026lt;br\u0026gt;- Identify the outermost shell of an atom.\u0026lt;br\u0026gt;- Count the number of valence electrons present in an atom.\u0026lt;br\u0026gt;- Predict the number of valence electrons in the atoms of groups 1, 2, and 13 to 18 using the periodic table.\u0026lt;br\u0026gt;","IS_ANALYTICS":"Y","VR_ENABLE":"Y","VR_SESSION_ENABLE":"Y","YOUTUBE_URL":null,"CONT_TYPE":"VR Module","CAT_NAME":"Valence electrons","ADMSUBJECT_ID":"820","ADMCOURSE_ID":"217","DISPLAY_NAME":"Cambridge - AS \u0026 A level - Chemistry","DISPLAY_NAME_AR":"Cambridge - AS \u0026 A level - Chemistry","SUBJECT_NAME":"Chemistry","SUBJECT_NAME_AR":"Chemistry","SUBJECT_DESC":"Chemistry","SUBJECT_DESC_AR":"Chemistry","SUBJECT_IMG":"","SUBJECT_BANNER_IMG":null,"SUBJECT_PRICE":null,"IS_FEATURED":"N","COURSE_NAME":"AS \u0026 A level","COUNTRY_ID":"296","SHORT_NAME":"Cambridge (IGCSE)","DOMAIN_NAME":"STEM"},{"CONT_ID":"169","CATEGORY_ID":"1","CONT_TITLE":"Lewis Dot Structures","CONT_SLUG":"lewis-dot-structures","CONT_TITLE_AR":"Lewis dot Structures","CONT_DESC":"\u003Ch3\u003EOverview:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003ELewis dot structures of atoms are the representations that show valence electrons as dots around the element\u2019s chemical symbol. Lewis dot structures of molecules are the representations that show the bonding between atoms and lone pairs of electrons.\u003C\/div\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Ch3\u003ELearning Objectives:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EAfter completing this module, you will be able to: \u003C\/div\u003E \r\n\u003Cdiv\u003E- Explain the steps to represent the \u0026#039;Lewis dot structure\u0026#039; of different atoms and molecules. \u003C\/div\u003E \r\n\u003Cdiv\u003E- Draw the \u0026#039;Lewis dot structures\u0026#039; of atoms and molecules.\u003C\/div\u003E","CONT_DESC_AR":"Lewis dot structures of atoms are the representations that show valence electrons as dots around the element\u0026amp;rsquo;s chemical symbol.Lewis dot structures of molecules are the representations that show the bonding between atoms and lone pairs of electrons.\u0026amp;nbsp;\u0026lt;br \/\u0026gt;\n\u0026lt;br \/\u0026gt;\n\u0026lt;strong\u0026gt;Learning Objectives\u0026lt;\/strong\u0026gt;\u0026lt;br \/\u0026gt;\n\u0026lt;br \/\u0026gt;\nIn this simulation, you will be able to:\u0026lt;br \/\u0026gt;\n\u0026amp;bull; explain steps involved in writing Lewis dot structures of atoms and molecules\u0026lt;br \/\u0026gt;\n\u0026amp;bull; draw Lewis dot structures of atoms and molecules","BACKING_FILE":"hs200069.apk","FILE_UID":null,"SCORM_COURSE_ID":null,"CONT_SRC":"","MOD_FILES":null,"FOLDER_NAME":null,"CONTTYPE_ID":"9","ANDROID_PKG":"com.umety.vr.hs200069","TOPIC_ID":"hs200069","IS_PUBLISH":"Y","IS_PUBLIC":"Y","CONT_PRICE":null,"PUBLIC_IMG":"thumb_HS200069.jpg","PUBLIC_BANNER_IMG":"HS200069.jpg","PUBLIC_VIDEO":"pvideo_hs200069.mp4","PUBLIC_VIDEO_URL":"https:\/\/youtu.be\/W0V5VQ3PcC4","DIST":null,"SHOW_ON_HOME":"N","CONTROLLER_REQUIRED":"Y","DOMAIN":"3","CONCEPT":"0","STATUS":"A","EXPIRY_DAYS":null,"CREATED_ON":"2018-01-19 07:16:38","CREATED_BY":"1","UPDATED_ON":"0000-00-00 00:00:00","UPDATED_BY":"2","CONT_ORDER":"0","X_ROTATION":null,"Y_ROTATION":null,"Z_ROTATION":null,"BG_COLOR":"0x000000","X_POSITION":null,"Y_POSITION":null,"Z_POSITION":null,"TEMP_DESC":"Overview:\u0026lt;br\u0026gt;\u0026lt;br\u0026gt;Lewis dot structures of atoms are the representations that show valence electrons as dots around the element\u2019s chemical symbol. Lewis dot structures of molecules are the representations that show the bonding between atoms and lone pairs of electrons. \u0026lt;br\u0026gt;\u0026lt;br\u0026gt;Learning objectives\u0026lt;br\u0026gt;\u0026lt;br\u0026gt;After completing this module, you will be able to:\u0026lt;br\u0026gt;\u0026amp;nbsp;- Explain the steps to represent the \u0026#039;Lewis dot structure\u0026#039; of different atoms and molecules.\u0026lt;br\u0026gt;\u0026amp;nbsp;- Draw the \u0026#039;Lewis dot structures\u0026#039; of atoms and molecules.\u0026lt;br\u0026gt;","IS_ANALYTICS":"Y","VR_ENABLE":"Y","VR_SESSION_ENABLE":"Y","YOUTUBE_URL":null,"CONT_TYPE":"VR Module","CAT_NAME":"Lewis dot structures","ADMSUBJECT_ID":"820","ADMCOURSE_ID":"217","DISPLAY_NAME":"Cambridge - AS \u0026 A level - Chemistry","DISPLAY_NAME_AR":"Cambridge - AS \u0026 A level - Chemistry","SUBJECT_NAME":"Chemistry","SUBJECT_NAME_AR":"Chemistry","SUBJECT_DESC":"Chemistry","SUBJECT_DESC_AR":"Chemistry","SUBJECT_IMG":"","SUBJECT_BANNER_IMG":null,"SUBJECT_PRICE":null,"IS_FEATURED":"N","COURSE_NAME":"AS \u0026 A level","COUNTRY_ID":"296","SHORT_NAME":"Cambridge (IGCSE)","DOMAIN_NAME":"STEM"},{"CONT_ID":"167","CATEGORY_ID":"1","CONT_TITLE":"Isoelectronic Species","CONT_SLUG":"isoelectronic-species","CONT_TITLE_AR":"Isoelectronic species","CONT_DESC":"\u003Ch3\u003EOverview:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EIsoelectronic species have the same number of electrons or a similar electronic configuration, and similar structure. Isoelectronic species can be atoms, ions or molecules. Neon (Ne) atoms and Sodium ion (Na\u207a) are isoelectronic, as both contain 10 electrons.\u003C\/div\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Ch3\u003ELearning Objectives:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EAfter completing this module, you will be able to:\u003C\/div\u003E \r\n\u003Cdiv\u003E- Define isoelectronic species.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Identify isoelectronic species of different elements.\u003C\/div\u003E","CONT_DESC_AR":"Isoelectronic species have the same number of electrons or a similar electronic configuration and similar structure. Isoelectronic species can be atoms, ions or molecules. Ne atoms and Na+ ions are isoelectronic, as both contain 10 electrons.\u0026lt;br \/\u0026gt;\n\u0026lt;br \/\u0026gt;\n\u0026lt;strong\u0026gt;Learning Objectives\u0026lt;\/strong\u0026gt;\u0026lt;br \/\u0026gt;\n\u0026lt;br \/\u0026gt;\nAt the end of the simulation, you will be able to:\u0026amp;nbsp;\u0026lt;br \/\u0026gt;\n\u0026amp;bull; define isoelectronic species\u0026lt;br \/\u0026gt;\n\u0026amp;bull; identify isoelectronic species of different elements","BACKING_FILE":"hs200052.apk","FILE_UID":null,"SCORM_COURSE_ID":null,"CONT_SRC":"","MOD_FILES":null,"FOLDER_NAME":null,"CONTTYPE_ID":"9","ANDROID_PKG":"com.umety.vr.hs200052","TOPIC_ID":"hs200052","IS_PUBLISH":"Y","IS_PUBLIC":"Y","CONT_PRICE":null,"PUBLIC_IMG":"thumb_HS200052.jpg","PUBLIC_BANNER_IMG":"HS200052.jpg","PUBLIC_VIDEO":"pvideo_hs200052.mp4","PUBLIC_VIDEO_URL":"https:\/\/youtu.be\/IJ7J0l0OUZg","DIST":null,"SHOW_ON_HOME":"N","CONTROLLER_REQUIRED":"Y","DOMAIN":"3","CONCEPT":"0","STATUS":"A","EXPIRY_DAYS":null,"CREATED_ON":"2018-01-19 07:16:38","CREATED_BY":"1","UPDATED_ON":"0000-00-00 00:00:00","UPDATED_BY":"2","CONT_ORDER":"0","X_ROTATION":null,"Y_ROTATION":null,"Z_ROTATION":null,"BG_COLOR":"0x000000","X_POSITION":null,"Y_POSITION":null,"Z_POSITION":null,"TEMP_DESC":"\u0026lt;div\u0026gt;Overview:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;Isoelectronic species have the same number of electrons or a similar electronic configuration, and similar structure. Isoelectronic species can be atoms, ions or molecules. Neon (Ne) atoms and Sodium ion (Na\u0026lt;span style=\u0026quot;color: rgb(38, 50, 56); font-family: Roboto, sans-serif;\u0026quot;\u0026gt;\u207a\u0026lt;\/span\u0026gt;) are isoelectronic, as both contain 10 electrons.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;Learning Objectives:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;div\u0026gt;After completing this module, you will be able to:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Define isoelectronic species.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Identify isoelectronic species of different elements.\u0026lt;\/div\u0026gt;\u0026lt;\/div\u0026gt;","IS_ANALYTICS":"Y","VR_ENABLE":"Y","VR_SESSION_ENABLE":"Y","YOUTUBE_URL":null,"CONT_TYPE":"VR Module","CAT_NAME":"Isoelectronic species","ADMSUBJECT_ID":"820","ADMCOURSE_ID":"217","DISPLAY_NAME":"Cambridge - AS \u0026 A level - Chemistry","DISPLAY_NAME_AR":"Cambridge - AS \u0026 A level - Chemistry","SUBJECT_NAME":"Chemistry","SUBJECT_NAME_AR":"Chemistry","SUBJECT_DESC":"Chemistry","SUBJECT_DESC_AR":"Chemistry","SUBJECT_IMG":"","SUBJECT_BANNER_IMG":null,"SUBJECT_PRICE":null,"IS_FEATURED":"N","COURSE_NAME":"AS \u0026 A level","COUNTRY_ID":"296","SHORT_NAME":"Cambridge (IGCSE)","DOMAIN_NAME":"STEM"},{"CONT_ID":"165","CATEGORY_ID":"1","CONT_TITLE":"Isotones","CONT_SLUG":"isotones","CONT_TITLE_AR":"Isotones","CONT_DESC":"\u003Ch3\u003EOverview:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EIsotones are atoms that have the same number of neutrons but a different number of protons. Boron-12 and carbon-13 are isotones, as both of them contain 7 neutrons.\u003C\/div\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Ch3\u003ELearning Objectives:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EAt the end of this module, you will be able to:\u003C\/div\u003E \r\n\u003Cdiv\u003E- Define isotones.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Identify isotones of different elements.\u003C\/div\u003E","CONT_DESC_AR":"Isotones have the same number of neutrons but a different number of protons. Boron-12 and carbon-13 are isotones, as both of them contain 7 neutrons.\u0026lt;br \/\u0026gt;\n\u0026lt;br \/\u0026gt;\n\u0026lt;strong\u0026gt;Learning Objectives\u0026lt;\/strong\u0026gt;\u0026lt;br \/\u0026gt;\n\u0026lt;br \/\u0026gt;\nAt the end of the simulation, you will be able to:\u0026lt;br \/\u0026gt;\n\u0026amp;bull; define isotones\u0026lt;br \/\u0026gt;\n\u0026amp;bull; identify isotones of different elements","BACKING_FILE":"hs200050.apk","FILE_UID":null,"SCORM_COURSE_ID":null,"CONT_SRC":"","MOD_FILES":null,"FOLDER_NAME":null,"CONTTYPE_ID":"9","ANDROID_PKG":"com.umety.vr.hs200050","TOPIC_ID":"hs200050","IS_PUBLISH":"Y","IS_PUBLIC":"Y","CONT_PRICE":null,"PUBLIC_IMG":"thumb_HS200050.jpg","PUBLIC_BANNER_IMG":"HS200050.jpg","PUBLIC_VIDEO":"pvideo_hs200050.mp4","PUBLIC_VIDEO_URL":"https:\/\/youtu.be\/RNhrWFaUeqQ","DIST":null,"SHOW_ON_HOME":"N","CONTROLLER_REQUIRED":"Y","DOMAIN":"3","CONCEPT":"0","STATUS":"A","EXPIRY_DAYS":null,"CREATED_ON":"2018-01-19 07:16:38","CREATED_BY":"1","UPDATED_ON":"0000-00-00 00:00:00","UPDATED_BY":"2","CONT_ORDER":"0","X_ROTATION":null,"Y_ROTATION":null,"Z_ROTATION":null,"BG_COLOR":"0x000000","X_POSITION":null,"Y_POSITION":null,"Z_POSITION":null,"TEMP_DESC":"\u0026lt;div\u0026gt;Overview:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;Isotones are atoms that have the same number of neutrons but a different number of protons. Boron-12 and carbon-13 are isotones, as both of them contain 7 neutrons.\u0026amp;nbsp;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;Learning Objectives:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;div\u0026gt;At the end of this module, you will be able to:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Define isotones.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Identify isotones of different elements.\u0026lt;\/div\u0026gt;\u0026lt;\/div\u0026gt;","IS_ANALYTICS":"Y","VR_ENABLE":"Y","VR_SESSION_ENABLE":"Y","YOUTUBE_URL":null,"CONT_TYPE":"VR Module","CAT_NAME":"Isotones","ADMSUBJECT_ID":"820","ADMCOURSE_ID":"217","DISPLAY_NAME":"Cambridge - AS \u0026 A level - Chemistry","DISPLAY_NAME_AR":"Cambridge - AS \u0026 A level - Chemistry","SUBJECT_NAME":"Chemistry","SUBJECT_NAME_AR":"Chemistry","SUBJECT_DESC":"Chemistry","SUBJECT_DESC_AR":"Chemistry","SUBJECT_IMG":"","SUBJECT_BANNER_IMG":null,"SUBJECT_PRICE":null,"IS_FEATURED":"N","COURSE_NAME":"AS \u0026 A level","COUNTRY_ID":"296","SHORT_NAME":"Cambridge (IGCSE)","DOMAIN_NAME":"STEM"},{"CONT_ID":"162","CATEGORY_ID":"1","CONT_TITLE":"Isobars","CONT_SLUG":"isobars","CONT_TITLE_AR":"Isobars","CONT_DESC":"\u003Ch3\u003EOverview:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EIsobars are atoms that have the same mass number, but a different atomic number. Hence isobars have the same number of nuclides, but a different number of protons.\u003C\/div\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Ch3\u003ELearning Objectives:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EAfter completing this module, you will be able to:\u003C\/div\u003E \r\n\u003Cdiv\u003E- Define isobars.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Identify isobars of different elements.\u003C\/div\u003E","CONT_DESC_AR":"Isobars have the same mass number, but a different atomic number. Hence isobars have the same number of nuclides, but a different number of protons.\u0026lt;br \/\u0026gt;\n\u0026lt;br \/\u0026gt;\n\u0026lt;strong\u0026gt;Learning Objectives\u0026lt;\/strong\u0026gt;\u0026lt;br \/\u0026gt;\n\u0026lt;br \/\u0026gt;\nAfter playing this simulation you will be able to:\u0026lt;br \/\u0026gt;\n\u0026amp;bull; define isobars\u0026lt;br \/\u0026gt;\n\u0026amp;bull; identify isobars of different elements\u0026lt;br \/\u0026gt;\n\u0026amp;bull; calculate the number of protons and neutrons in different isobars","BACKING_FILE":"hs200025.apk","FILE_UID":null,"SCORM_COURSE_ID":null,"CONT_SRC":"","MOD_FILES":null,"FOLDER_NAME":null,"CONTTYPE_ID":"9","ANDROID_PKG":"com.umety.vr.hs200025","TOPIC_ID":"hs200025","IS_PUBLISH":"Y","IS_PUBLIC":"Y","CONT_PRICE":null,"PUBLIC_IMG":"thumb_HS200025.jpg","PUBLIC_BANNER_IMG":"HS200025.jpg","PUBLIC_VIDEO":"pvideo_hs200025.mp4","PUBLIC_VIDEO_URL":"https:\/\/youtu.be\/LOlP2PuVudo","DIST":null,"SHOW_ON_HOME":"N","CONTROLLER_REQUIRED":"Y","DOMAIN":"3","CONCEPT":"0","STATUS":"A","EXPIRY_DAYS":null,"CREATED_ON":"2018-01-19 07:16:38","CREATED_BY":"1","UPDATED_ON":"0000-00-00 00:00:00","UPDATED_BY":"2","CONT_ORDER":"0","X_ROTATION":null,"Y_ROTATION":null,"Z_ROTATION":null,"BG_COLOR":"0x000000","X_POSITION":null,"Y_POSITION":null,"Z_POSITION":null,"TEMP_DESC":"\u0026lt;div\u0026gt;Overview:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;Isobars are atoms that have the same mass number, but a different atomic number. Hence isobars have the same number of nuclides, but a different number of protons.\u0026amp;nbsp;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;Learning Objectives:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;div\u0026gt;After completing this module, you will be able to:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Define isobars.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Identify isobars of different elements.\u0026lt;\/div\u0026gt;\u0026lt;\/div\u0026gt;","IS_ANALYTICS":"Y","VR_ENABLE":"Y","VR_SESSION_ENABLE":"Y","YOUTUBE_URL":null,"CONT_TYPE":"VR Module","CAT_NAME":"Isobars","ADMSUBJECT_ID":"820","ADMCOURSE_ID":"217","DISPLAY_NAME":"Cambridge - AS \u0026 A level - Chemistry","DISPLAY_NAME_AR":"Cambridge - AS \u0026 A level - Chemistry","SUBJECT_NAME":"Chemistry","SUBJECT_NAME_AR":"Chemistry","SUBJECT_DESC":"Chemistry","SUBJECT_DESC_AR":"Chemistry","SUBJECT_IMG":"","SUBJECT_BANNER_IMG":null,"SUBJECT_PRICE":null,"IS_FEATURED":"N","COURSE_NAME":"AS \u0026 A level","COUNTRY_ID":"296","SHORT_NAME":"Cambridge (IGCSE)","DOMAIN_NAME":"STEM"},{"CONT_ID":"159","CATEGORY_ID":"1","CONT_TITLE":"Isotopes","CONT_SLUG":"isotopes","CONT_TITLE_AR":"Isotopes","CONT_DESC":"\u003Ch3\u003EOverview:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EIsotopes are atoms that have the same number of protons and electrons, but a different number of neutrons. A hydrogen atom has three known isotopes: hydrogen, deuterium and tritium.\u003C\/div\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Ch3\u003ELearning Objectives:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EAfter completing this module, you will be able to:\u003C\/div\u003E \r\n\u003Cdiv\u003E- Define isotopes. \u003C\/div\u003E \r\n\u003Cdiv\u003E- Identify isotopes of different elements. \u003C\/div\u003E \r\n\u003Cdiv\u003E- Calculate the number of protons and neutrons in different isotopes.\u003C\/div\u003E","CONT_DESC_AR":"Isotopes of an element have the same number of protons and electrons, but a different number of neutrons. A hydrogen atom has three known isotopes: \u0026amp;nbsp;hydrogen, deuterium and tritium.\u0026lt;br \/\u0026gt;\n\u0026lt;br \/\u0026gt;\n\u0026lt;strong\u0026gt;Learning Objectives\u0026lt;\/strong\u0026gt;\u0026lt;br \/\u0026gt;\n\u0026lt;br \/\u0026gt;\nIn this simulation, you will be able to:\u0026lt;br \/\u0026gt;\n\u0026amp;bull; define isotopes\u0026amp;nbsp;\u0026lt;br \/\u0026gt;\n\u0026amp;bull; identify isotopes of different elements\u0026amp;nbsp;\u0026lt;br \/\u0026gt;\n\u0026amp;bull; calculate the number of protons and neutrons in different isotopes","BACKING_FILE":null,"FILE_UID":null,"SCORM_COURSE_ID":null,"CONT_SRC":"","MOD_FILES":null,"FOLDER_NAME":null,"CONTTYPE_ID":"9","ANDROID_PKG":"com.umety.vr.hs200024","TOPIC_ID":"hs200024","IS_PUBLISH":"Y","IS_PUBLIC":"Y","CONT_PRICE":null,"PUBLIC_IMG":"thumb_HS200024.jpg","PUBLIC_BANNER_IMG":"HS200024.jpg","PUBLIC_VIDEO":"pvideo_hs200024.mp4","PUBLIC_VIDEO_URL":"https:\/\/youtu.be\/f4sZdLZU03k","DIST":null,"SHOW_ON_HOME":"N","CONTROLLER_REQUIRED":"Y","DOMAIN":"3","CONCEPT":"0","STATUS":"A","EXPIRY_DAYS":null,"CREATED_ON":"2018-01-19 07:16:38","CREATED_BY":"1","UPDATED_ON":"0000-00-00 00:00:00","UPDATED_BY":"2","CONT_ORDER":"0","X_ROTATION":null,"Y_ROTATION":null,"Z_ROTATION":null,"BG_COLOR":"0x000000","X_POSITION":null,"Y_POSITION":null,"Z_POSITION":null,"TEMP_DESC":"\u0026lt;div\u0026gt;Overview:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;Isotopes are atoms that have the same number of protons and electrons, but a different number of neutrons. A hydrogen atom has three known isotopes:\u0026amp;nbsp; hydrogen, deuterium and tritium.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;Learning Objectives:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;div\u0026gt;After completing this module, you will be able to:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Define isotopes.\u0026amp;nbsp;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Identify isotopes of different elements.\u0026amp;nbsp;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Calculate the number of protons and neutrons in different isotopes.\u0026lt;\/div\u0026gt;\u0026lt;\/div\u0026gt;","IS_ANALYTICS":"Y","VR_ENABLE":"Y","VR_SESSION_ENABLE":"Y","YOUTUBE_URL":null,"CONT_TYPE":"VR Module","CAT_NAME":"Isotopes","ADMSUBJECT_ID":"820","ADMCOURSE_ID":"217","DISPLAY_NAME":"Cambridge - AS \u0026 A level - Chemistry","DISPLAY_NAME_AR":"Cambridge - AS \u0026 A level - Chemistry","SUBJECT_NAME":"Chemistry","SUBJECT_NAME_AR":"Chemistry","SUBJECT_DESC":"Chemistry","SUBJECT_DESC_AR":"Chemistry","SUBJECT_IMG":"","SUBJECT_BANNER_IMG":null,"SUBJECT_PRICE":null,"IS_FEATURED":"N","COURSE_NAME":"AS \u0026 A level","COUNTRY_ID":"296","SHORT_NAME":"Cambridge (IGCSE)","DOMAIN_NAME":"STEM"},{"CONT_ID":"148","CATEGORY_ID":"1","CONT_TITLE":"Periodic Trends-Atomic Radii","CONT_SLUG":"periodic-trends-atomic-radii","CONT_TITLE_AR":"Periodic Trends: Atomic Radii","CONT_DESC":"\u003Ch3\u003EOverview:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EThe atomic radius of a chemical element is the distance from the center of the nucleus to the outmost boundary of the surrounding cloud of electrons. On moving left to right in the periodic table, the atomic radius decreases with the atomic number. Down the group, the atomic radius increases.\u003C\/div\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Ch3\u003ELearning Objectives:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EAfter completing this module, you will be able to:\u003C\/div\u003E \r\n\u003Cdiv\u003E- Predict the trends of atomic radii in the periodic table.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Compare the atomic radii of the elements.\u003C\/div\u003E","CONT_DESC_AR":"The atomic radius of a chemical element is the distance from the center of the nucleus to the boundary of the surrounding cloud of electrons. On moving left to right in the periodic table, the atomic radius decreases with the atomic number. Down the group, the atomic radius increases in conjunction to the atomic number.\u0026lt;br \/\u0026gt;\n\u0026lt;br \/\u0026gt;\n\u0026lt;strong\u0026gt;Learning Objectives\u0026lt;\/strong\u0026gt;\u0026lt;br \/\u0026gt;\n\u0026lt;br \/\u0026gt;\nAfter playing the simulation, you will be able to:\u0026amp;nbsp;\u0026lt;br \/\u0026gt;\n\u0026amp;bull; calculate the valency of elements\u0026lt;br \/\u0026gt;\n\u0026amp;bull; predict the placement of elements in the periodic table using valency","BACKING_FILE":null,"FILE_UID":null,"SCORM_COURSE_ID":null,"CONT_SRC":"","MOD_FILES":null,"FOLDER_NAME":null,"CONTTYPE_ID":"9","ANDROID_PKG":"com.umety.vr.hs200012","TOPIC_ID":"hs200012","IS_PUBLISH":"Y","IS_PUBLIC":"Y","CONT_PRICE":null,"PUBLIC_IMG":"thumb_HS200012.jpg","PUBLIC_BANNER_IMG":"hs200012.jpg","PUBLIC_VIDEO":"pvideo_hs200012.mp4","PUBLIC_VIDEO_URL":"https:\/\/youtu.be\/InBee94xfgk","DIST":null,"SHOW_ON_HOME":"N","CONTROLLER_REQUIRED":"Y","DOMAIN":"3","CONCEPT":"0","STATUS":"A","EXPIRY_DAYS":null,"CREATED_ON":"2018-01-19 07:16:38","CREATED_BY":"1","UPDATED_ON":"0000-00-00 00:00:00","UPDATED_BY":"2","CONT_ORDER":"0","X_ROTATION":null,"Y_ROTATION":null,"Z_ROTATION":null,"BG_COLOR":"0x000000","X_POSITION":null,"Y_POSITION":null,"Z_POSITION":null,"TEMP_DESC":"\u0026lt;div\u0026gt;Overview:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;The atomic radius of a chemical element is the distance from the center of the nucleus to the outmost boundary of the surrounding cloud of electrons. On moving left to right in the periodic table, the atomic radius decreases with the atomic number. Down the group, the atomic radius increases.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;Learning Objectives:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;div\u0026gt;After completing this module, you will be able to:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Predict the trends of atomic radii in the periodic table.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Compare the atomic radii of the elements.\u0026lt;\/div\u0026gt;\u0026lt;\/div\u0026gt;","IS_ANALYTICS":"Y","VR_ENABLE":"Y","VR_SESSION_ENABLE":"Y","YOUTUBE_URL":null,"CONT_TYPE":"VR Module","CAT_NAME":"Periodic Trends: Atomic Radii","ADMSUBJECT_ID":"820","ADMCOURSE_ID":"217","DISPLAY_NAME":"Cambridge - AS \u0026 A level - Chemistry","DISPLAY_NAME_AR":"Cambridge - AS \u0026 A level - Chemistry","SUBJECT_NAME":"Chemistry","SUBJECT_NAME_AR":"Chemistry","SUBJECT_DESC":"Chemistry","SUBJECT_DESC_AR":"Chemistry","SUBJECT_IMG":"","SUBJECT_BANNER_IMG":null,"SUBJECT_PRICE":null,"IS_FEATURED":"N","COURSE_NAME":"AS \u0026 A level","COUNTRY_ID":"296","SHORT_NAME":"Cambridge (IGCSE)","DOMAIN_NAME":"STEM"},{"CONT_ID":"146","CATEGORY_ID":"1","CONT_TITLE":"Periodic Trends-Valency","CONT_SLUG":"periodic-trends-valency","CONT_TITLE_AR":"Periodic Trends: Valency","CONT_DESC":"\u003Ch3\u003EOverview:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EIn the atoms, the electrons which are found in the outermost shell are generally known as valence electrons and the number of valence electrons determines the valency of an atom. The valency of atoms of 1st, 2nd, 13th and 14th group elements are generally given as the number of valence electrons. And the valency of 15th to 18th group elements can be calculated by subtracting the number of valence electrons from number eight.\u003C\/div\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Ch3\u003ELearning Objectives:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EAfter completing this module, you will be able to: \u003C\/div\u003E \r\n\u003Cdiv\u003E- Calculate the valency of an element using the number of valence electrons.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Determine the valency of an element with the help of its position in the periodic table.\u003C\/div\u003E","CONT_DESC_AR":"In the atoms, the electrons which are found in the outermost shell are generally known as valence electrons and the number of valence electrons determines the valency of an atom.\u0026amp;nbsp;The valency of atoms of 1st, 2nd, 13th and 14th group elements are generally given as the number of valence electron.\u0026amp;nbsp;And the valency of 15th to 18th group elements can be calculated by subtracting the number of valence electrons from number eight.\u0026lt;br \/\u0026gt;\n\u0026lt;br \/\u0026gt;\n\u0026lt;strong\u0026gt;Learning objectives\u0026amp;nbsp;\u0026lt;\/strong\u0026gt;\u0026lt;br \/\u0026gt;\n\u0026lt;br \/\u0026gt;\nAfter playing the simulation, you will be able to:\u0026amp;nbsp;\u0026lt;br \/\u0026gt;\n\u0026amp;bull; calculate the valency of elements\u0026lt;br \/\u0026gt;\n\u0026amp;bull; predict the placement of elements in the periodic table using valency","BACKING_FILE":"hs200011.apk","FILE_UID":null,"SCORM_COURSE_ID":null,"CONT_SRC":"","MOD_FILES":null,"FOLDER_NAME":null,"CONTTYPE_ID":"9","ANDROID_PKG":"com.umety.vr.hs200011","TOPIC_ID":"hs200011","IS_PUBLISH":"Y","IS_PUBLIC":"Y","CONT_PRICE":null,"PUBLIC_IMG":"thumb_HS200011.jpg","PUBLIC_BANNER_IMG":"hs200011.jpg","PUBLIC_VIDEO":"pvideo_hs200011.mp4","PUBLIC_VIDEO_URL":"https:\/\/youtu.be\/XV474BAXvVQ","DIST":null,"SHOW_ON_HOME":"N","CONTROLLER_REQUIRED":"Y","DOMAIN":"3","CONCEPT":"0","STATUS":"A","EXPIRY_DAYS":null,"CREATED_ON":"2018-01-19 07:16:38","CREATED_BY":"1","UPDATED_ON":"0000-00-00 00:00:00","UPDATED_BY":"2","CONT_ORDER":"0","X_ROTATION":null,"Y_ROTATION":null,"Z_ROTATION":null,"BG_COLOR":"0x000000","X_POSITION":null,"Y_POSITION":null,"Z_POSITION":null,"TEMP_DESC":"\u0026lt;div\u0026gt;Overview:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;In the atoms, the electrons which are found in the outermost shell are generally known as valence electrons and the number of valence electrons determines the valency of an atom. The valency of atoms of 1st, 2nd, 13th and 14th group elements are generally given as the number of valence electrons. And the valency of 15th to 18th group elements can be calculated by subtracting the number of valence electrons from number eight.\u0026amp;nbsp;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;Learning Objectives:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;div\u0026gt;After completing this module, you will be able to:\u0026amp;nbsp;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Calculate the valency of an element using the number of valence electrons.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Determine the valency of an element with the help of its position in the periodic table.\u0026lt;\/div\u0026gt;\u0026lt;\/div\u0026gt;","IS_ANALYTICS":"Y","VR_ENABLE":"Y","VR_SESSION_ENABLE":"Y","YOUTUBE_URL":null,"CONT_TYPE":"VR Module","CAT_NAME":"Periodic Trends: Valency","ADMSUBJECT_ID":"820","ADMCOURSE_ID":"217","DISPLAY_NAME":"Cambridge - AS \u0026 A level - Chemistry","DISPLAY_NAME_AR":"Cambridge - AS \u0026 A level - Chemistry","SUBJECT_NAME":"Chemistry","SUBJECT_NAME_AR":"Chemistry","SUBJECT_DESC":"Chemistry","SUBJECT_DESC_AR":"Chemistry","SUBJECT_IMG":"","SUBJECT_BANNER_IMG":null,"SUBJECT_PRICE":null,"IS_FEATURED":"N","COURSE_NAME":"AS \u0026 A level","COUNTRY_ID":"296","SHORT_NAME":"Cambridge (IGCSE)","DOMAIN_NAME":"STEM"},{"CONT_ID":"144","CATEGORY_ID":"1","CONT_TITLE":"Electron Distribution in Different Shells","CONT_SLUG":"electron-distribution-in-different-shells","CONT_TITLE_AR":"Electron Distribution in Different Shells","CONT_DESC":"\u003Ch3\u003EOverview:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EElectrons are arranged in energy levels, or shells, around the nucleus of an atom. The shell nearest to the nucleus has the least energy and subsequent shells have progressively more energy. Electrons first occupy lowest-energy shell, subsequent shells are occupied according to increasing order of energy. The maximum number of electrons that can be accommodated in any energy level is given by 2n\u00b2 where n is the number of the energy level, such as 1, 2, 3, 4...\u003C\/div\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Ch3\u003ELearning Objectives:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EAfter completing this module, you will be able to:\u003C\/div\u003E \r\n\u003Cdiv\u003E- Explain the rules for filling electrons in different atomic shells.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Arrange electrons in different atomic shells up to first 20 elements.\u003C\/div\u003E","CONT_DESC_AR":"Electrons are arranged in energy levels, or shells, around the nucleus of an atom. The shell nearest the nucleus has the least energy and subsequent shells have progressively more energy. The electron first occupy the lowest-energy shell, subsequent shells are occupied according to increasing order of energy. The maximum number of electrons that can be accommodated in any energy level is given by 2n2 where n is the number of the energy level, such as 1, 2, 3, 4...\u0026lt;br \/\u0026gt;\n\u0026lt;br \/\u0026gt;\n\u0026lt;strong\u0026gt;Learning objectives\u0026amp;nbsp;\u0026lt;\/strong\u0026gt;\u0026lt;br \/\u0026gt;\n\u0026lt;br \/\u0026gt;\nIn this simulation, you will be able to:\u0026lt;br \/\u0026gt;\n\u0026amp;bull; explain the rules for filling different atomic shells with electrons\u0026lt;br \/\u0026gt;\n\u0026amp;bull; arrange electrons in different atomic shells for the first 20 elements","BACKING_FILE":null,"FILE_UID":null,"SCORM_COURSE_ID":null,"CONT_SRC":"","MOD_FILES":null,"FOLDER_NAME":null,"CONTTYPE_ID":"9","ANDROID_PKG":"com.umety.vr.hs200004","TOPIC_ID":"hs200004","IS_PUBLISH":"Y","IS_PUBLIC":"Y","CONT_PRICE":null,"PUBLIC_IMG":"thumb_HS200004.jpg","PUBLIC_BANNER_IMG":"HS200004.jpg","PUBLIC_VIDEO":"pvideo_hs200004.mp4","PUBLIC_VIDEO_URL":"https:\/\/youtu.be\/rzCLxuiGR_A","DIST":null,"SHOW_ON_HOME":"N","CONTROLLER_REQUIRED":"Y","DOMAIN":"3","CONCEPT":"0","STATUS":"A","EXPIRY_DAYS":null,"CREATED_ON":"2018-01-19 07:16:38","CREATED_BY":"1","UPDATED_ON":"0000-00-00 00:00:00","UPDATED_BY":"2","CONT_ORDER":"0","X_ROTATION":null,"Y_ROTATION":null,"Z_ROTATION":null,"BG_COLOR":"0x000000","X_POSITION":null,"Y_POSITION":null,"Z_POSITION":null,"TEMP_DESC":"\u0026lt;div\u0026gt;Overview:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;div\u0026gt;Electrons are arranged in energy levels, or shells, around the nucleus of an atom. The shell nearest to the nucleus has the least energy and subsequent shells have progressively more energy. Electrons first occupy lowest-energy shell, subsequent shells are occupied according to increasing order of energy. The maximum number of electrons that can be accommodated in any energy level is given by 2n\u00b2 where n is the number of the energy level, such as 1, 2, 3, 4...\u0026lt;\/div\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;Learning Objectives:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;div\u0026gt;After completing this module, you will be able to:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Explain the rules for filling electrons in different atomic shells.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Arrange electrons in different atomic shells up to first 20 elements.\u0026lt;\/div\u0026gt;\u0026lt;\/div\u0026gt;","IS_ANALYTICS":"Y","VR_ENABLE":"Y","VR_SESSION_ENABLE":"Y","YOUTUBE_URL":null,"CONT_TYPE":"VR Module","CAT_NAME":"Electron Distribution in Different Shells","ADMSUBJECT_ID":"820","ADMCOURSE_ID":"217","DISPLAY_NAME":"Cambridge - AS \u0026 A level - Chemistry","DISPLAY_NAME_AR":"Cambridge - AS \u0026 A level - Chemistry","SUBJECT_NAME":"Chemistry","SUBJECT_NAME_AR":"Chemistry","SUBJECT_DESC":"Chemistry","SUBJECT_DESC_AR":"Chemistry","SUBJECT_IMG":"","SUBJECT_BANNER_IMG":null,"SUBJECT_PRICE":null,"IS_FEATURED":"N","COURSE_NAME":"AS \u0026 A level","COUNTRY_ID":"296","SHORT_NAME":"Cambridge (IGCSE)","DOMAIN_NAME":"STEM"},{"CONT_ID":"96","CATEGORY_ID":"1","CONT_TITLE":"The Molecule","CONT_SLUG":"the-molecules","CONT_TITLE_AR":"The Molecule","CONT_DESC":"\u003Ch3\u003EOverview:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EA molecule is a group of atoms bonded together. Molecules can be monatomic, diatomic or polyatomic on the basis of the number of atoms present in them.\u003C\/div\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Ch3\u003ELearning Objectives:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EAfter completing this module, you will be able to:\u003C\/div\u003E \r\n\u003Cdiv\u003E- Define molecules.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Calculate the atomicity of different molecules.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Identify monoatomic, diatomic and polyatomic molecules.\u003C\/div\u003E","CONT_DESC_AR":"A molecule is a group of atoms bonded together. Molecules can be monoatomic, diatomic or polyatomic on the basis of the number of atoms present in them.\u0026lt;br \/\u0026gt;\n\u0026amp;nbsp;\u0026lt;br \/\u0026gt;\n\u0026lt;strong\u0026gt;Learning Objectives\u0026lt;\/strong\u0026gt;\u0026lt;br \/\u0026gt;\n\u0026lt;br \/\u0026gt;\nIn this simulation, you will be able to:\u0026lt;br \/\u0026gt;\n\u0026amp;bull; define molecules\u0026lt;br \/\u0026gt;\n\u0026amp;bull; calculate atomicity of a molecule\u0026lt;br \/\u0026gt;\n\u0026amp;bull; identify monoatomic, diatomic and polyatomic molecules","BACKING_FILE":null,"FILE_UID":null,"SCORM_COURSE_ID":null,"CONT_SRC":"","MOD_FILES":null,"FOLDER_NAME":null,"CONTTYPE_ID":"9","ANDROID_PKG":"com.umety.vr.ms200077","TOPIC_ID":"ms200077","IS_PUBLISH":"Y","IS_PUBLIC":"Y","CONT_PRICE":null,"PUBLIC_IMG":"thumb_MS200077.jpg","PUBLIC_BANNER_IMG":"MS200077.jpg","PUBLIC_VIDEO":"pvideo_ms200077.mp4","PUBLIC_VIDEO_URL":"https:\/\/youtu.be\/-MxyzLjRApc","DIST":null,"SHOW_ON_HOME":"N","CONTROLLER_REQUIRED":"Y","DOMAIN":"3","CONCEPT":"0","STATUS":"A","EXPIRY_DAYS":null,"CREATED_ON":"2018-01-19 07:16:38","CREATED_BY":"1","UPDATED_ON":"0000-00-00 00:00:00","UPDATED_BY":"2","CONT_ORDER":"0","X_ROTATION":null,"Y_ROTATION":null,"Z_ROTATION":null,"BG_COLOR":"0x000000","X_POSITION":null,"Y_POSITION":null,"Z_POSITION":null,"TEMP_DESC":"Overview:\u0026lt;br\u0026gt;\u0026lt;br\u0026gt;A molecule is a group of atoms bonded together. Molecules can be monatomic, diatomic or polyatomic on the basis of the number of atoms present in them.\u0026lt;br\u0026gt;\u0026lt;br\u0026gt;Learning objectives\u0026lt;br\u0026gt;\u0026lt;br\u0026gt;\u0026lt;div\u0026gt;After completing this module, you will be able to:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Define molecules.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Calculate the atomicity of different molecules.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Identify monoatomic, diatomic and polyatomic molecules.\u0026lt;\/div\u0026gt;","IS_ANALYTICS":"Y","VR_ENABLE":"Y","VR_SESSION_ENABLE":"Y","YOUTUBE_URL":null,"CONT_TYPE":"VR Module","CAT_NAME":"The Molecules","ADMSUBJECT_ID":"820","ADMCOURSE_ID":"217","DISPLAY_NAME":"Cambridge - AS \u0026 A level - Chemistry","DISPLAY_NAME_AR":"Cambridge - AS \u0026 A level - Chemistry","SUBJECT_NAME":"Chemistry","SUBJECT_NAME_AR":"Chemistry","SUBJECT_DESC":"Chemistry","SUBJECT_DESC_AR":"Chemistry","SUBJECT_IMG":"","SUBJECT_BANNER_IMG":null,"SUBJECT_PRICE":null,"IS_FEATURED":"N","COURSE_NAME":"AS \u0026 A level","COUNTRY_ID":"296","SHORT_NAME":"Cambridge (IGCSE)","DOMAIN_NAME":"STEM"},{"CONT_ID":"59","CATEGORY_ID":"1","CONT_TITLE":"Phase Change: Melting and Freezing","CONT_SLUG":"phase-change-melting-and-freezing","CONT_TITLE_AR":"Phase Change-Melting and Freezing","CONT_DESC":"\u003Ch3\u003EOverview:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EIf a solid matter gains enough heat, it changes its state from solid to liquid, causing melting. On the other hand, when a solid matter loses heat, it causes a process called freezing. In freezing, the motion of atoms or molecules slows down.\u003C\/div\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Ch3\u003ELearning Objectives:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EAfter completing this module, you will be able to:\u003C\/div\u003E \r\n\u003Cdiv\u003E- Define melting and freezing.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Explain how solid state and liquid state of matter can be interchanged.\u003C\/div\u003E","CONT_DESC_AR":"If solid matter gains enough heat, it changes state from solid to liquid, causing melting. The inverse of melting is called freezing, changing from a liquid state to solid, in which atoms and molecules lose heat and come together, slowing down motion.\u0026lt;br \/\u0026gt;\n\u0026lt;br \/\u0026gt;\n\u0026lt;strong\u0026gt;Learning Objectives:\u0026lt;\/strong\u0026gt;\u0026lt;br \/\u0026gt;\n\u0026lt;br \/\u0026gt;\nIn this simulation, you will be able to:\u0026lt;br \/\u0026gt;\n- Define melting and freezing\u0026lt;br \/\u0026gt;\n- Explain how a solid state and liquid state of matter can be interchanged","BACKING_FILE":null,"FILE_UID":null,"SCORM_COURSE_ID":null,"CONT_SRC":"","MOD_FILES":null,"FOLDER_NAME":null,"CONTTYPE_ID":"9","ANDROID_PKG":"com.umety.vr.ms200018","TOPIC_ID":"ms200018","IS_PUBLISH":"Y","IS_PUBLIC":"Y","CONT_PRICE":null,"PUBLIC_IMG":"thumb_MS200018.jpg","PUBLIC_BANNER_IMG":"MS200018.jpg","PUBLIC_VIDEO":"pvideo_ms200018.mp4","PUBLIC_VIDEO_URL":"https:\/\/youtu.be\/_wM6VCKEABQ","DIST":null,"SHOW_ON_HOME":"N","CONTROLLER_REQUIRED":"Y","DOMAIN":"3","CONCEPT":"0","STATUS":"A","EXPIRY_DAYS":null,"CREATED_ON":"2018-01-19 07:16:38","CREATED_BY":"1","UPDATED_ON":"0000-00-00 00:00:00","UPDATED_BY":"2","CONT_ORDER":"0","X_ROTATION":null,"Y_ROTATION":null,"Z_ROTATION":null,"BG_COLOR":"0x000000","X_POSITION":null,"Y_POSITION":null,"Z_POSITION":null,"TEMP_DESC":"\u0026lt;div\u0026gt;Overview:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;div\u0026gt;If a solid matter gains enough heat, it changes its state from solid to liquid, causing melting. On the other hand, when a solid matter loses heat, it causes a process called freezing. In freezing, the motion of atoms or molecules slows down.\u0026lt;\/div\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;Learning Objectives:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;div\u0026gt;After completing this module, you will be able to:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Define melting and freezing.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Explain how solid state and liquid state of matter can be interchanged.\u0026lt;\/div\u0026gt;\u0026lt;\/div\u0026gt;","IS_ANALYTICS":"Y","VR_ENABLE":"Y","VR_SESSION_ENABLE":"Y","YOUTUBE_URL":null,"CONT_TYPE":"VR Module","CAT_NAME":"Phase Change: Melting and freezing","ADMSUBJECT_ID":"820","ADMCOURSE_ID":"217","DISPLAY_NAME":"Cambridge - AS \u0026 A level - Chemistry","DISPLAY_NAME_AR":"Cambridge - AS \u0026 A level - Chemistry","SUBJECT_NAME":"Chemistry","SUBJECT_NAME_AR":"Chemistry","SUBJECT_DESC":"Chemistry","SUBJECT_DESC_AR":"Chemistry","SUBJECT_IMG":"","SUBJECT_BANNER_IMG":null,"SUBJECT_PRICE":null,"IS_FEATURED":"N","COURSE_NAME":"AS \u0026 A level","COUNTRY_ID":"296","SHORT_NAME":"Cambridge (IGCSE)","DOMAIN_NAME":"STEM"},{"CONT_ID":"56","CATEGORY_ID":"1","CONT_TITLE":"States of Matter","CONT_SLUG":"states-of-matter","CONT_TITLE_AR":"States of Matter","CONT_DESC":"\u003Ch3\u003EOverview:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EMatter exists in three states: solid, liquid, and gas. Particles of various types of matter have different characteristics. The particles in solids are packed very closely. The spaces between the particles of liquids are almost the same as in solids.\u003C\/div\u003E \r\n\u003Cdiv\u003EBut, the particles of liquids are free to move. The particles in a gas have a high amount of energy, which makes it very easy to break apart gas particles.\u003C\/div\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Ch3\u003ELearning Objectives:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EAfter completing this module, you will be able to:\u003C\/div\u003E \r\n\u003Cdiv\u003E- Identify different states of matter.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Explain the characteristics of the particles of matter.\u003C\/div\u003E","CONT_DESC_AR":"Matter exists in three states: solid, liquid, and gas.\u003C\/br\u003E\r\nParticles of various types of matter have different characteristics.\u003C\/br\u003E\r\nThe particles in solids are packed very closely. The spaces between the particles of liquids are almost the same as in solids.\u003C\/br\u003E\r\nBut, the particles of liquids are free to move. The particles in a gas have a high amount of energy, which makes it very easy to break apart gas particles.\u003C\/br\u003E\u003C\/br\u003E\r\n\u003Cstrong\u003ELearning Objectives:\u003C\/strong\u003E\u003C\/br\u003E\u003C\/br\u003E\r\nIn this simulation, you will be able to:\u003C\/br\u003E\r\n- identify different states of matter\u003C\/br\u003E\r\n- explain the characteristics of particles of matter","BACKING_FILE":"ms200013.apk","FILE_UID":null,"SCORM_COURSE_ID":null,"CONT_SRC":"","MOD_FILES":null,"FOLDER_NAME":null,"CONTTYPE_ID":"9","ANDROID_PKG":"com.umety.vr.ms200013","TOPIC_ID":"ms200013","IS_PUBLISH":"Y","IS_PUBLIC":"Y","CONT_PRICE":null,"PUBLIC_IMG":"thumb_MS200013.jpg","PUBLIC_BANNER_IMG":"MS200013.jpg","PUBLIC_VIDEO":"pvideo_ms200013.mp4","PUBLIC_VIDEO_URL":"https:\/\/youtu.be\/IjS0e_2CV6o","DIST":null,"SHOW_ON_HOME":"N","CONTROLLER_REQUIRED":"Y","DOMAIN":"3","CONCEPT":"0","STATUS":"A","EXPIRY_DAYS":null,"CREATED_ON":"2018-01-19 07:16:38","CREATED_BY":"1","UPDATED_ON":"0000-00-00 00:00:00","UPDATED_BY":"2","CONT_ORDER":"0","X_ROTATION":null,"Y_ROTATION":null,"Z_ROTATION":null,"BG_COLOR":"0x000000","X_POSITION":null,"Y_POSITION":null,"Z_POSITION":null,"TEMP_DESC":"\u0026lt;div\u0026gt;Overview:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;div\u0026gt;Matter exists in three states: solid, liquid, and gas. Particles of various types of matter have different characteristics. The particles in solids are packed very closely. The spaces between the particles of liquids are almost the same as in solids.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;But, the particles of liquids are free to move. The particles in a gas have a high amount of energy, which makes it very easy to break apart gas particles.\u0026lt;\/div\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;Learning Objectives:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;br\u0026gt;\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;\u0026lt;div\u0026gt;After completing this module, you will be able to:\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Identify different states of matter.\u0026lt;\/div\u0026gt;\u0026lt;div\u0026gt;- Explain the characteristics of the particles of matter.\u0026lt;\/div\u0026gt;\u0026lt;\/div\u0026gt;","IS_ANALYTICS":"Y","VR_ENABLE":"Y","VR_SESSION_ENABLE":"Y","YOUTUBE_URL":null,"CONT_TYPE":"VR Module","CAT_NAME":"States of Matter","ADMSUBJECT_ID":"820","ADMCOURSE_ID":"217","DISPLAY_NAME":"Cambridge - AS \u0026 A level - Chemistry","DISPLAY_NAME_AR":"Cambridge - AS \u0026 A level - Chemistry","SUBJECT_NAME":"Chemistry","SUBJECT_NAME_AR":"Chemistry","SUBJECT_DESC":"Chemistry","SUBJECT_DESC_AR":"Chemistry","SUBJECT_IMG":"","SUBJECT_BANNER_IMG":null,"SUBJECT_PRICE":null,"IS_FEATURED":"N","COURSE_NAME":"AS \u0026 A level","COUNTRY_ID":"296","SHORT_NAME":"Cambridge (IGCSE)","DOMAIN_NAME":"STEM"}],"levelObject":["Periodic Table","Atom","Elements","Bohr\u0027s Atomic Model"],"contData":{"CONT_ID":"504","CATEGORY_ID":"1","CONT_TITLE":"Today\u0027s Periodic Table","CONT_SLUG":"todays-periodic-table","CONT_TITLE_AR":"","CONT_DESC":"\u003Ch3\u003EOverview:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EThe Periodic table is the systematic arrangement of 118 elements in the increasing order of their atomic number. The rows in the periodic table are called periods and the columns in the periodic table are called groups.\u003C\/div\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Ch3\u003ELearning Objectives:\u003C\/h3\u003E \r\n\u003Cdiv\u003E \r\n \u003Cbr\u003E \r\n\u003C\/div\u003E \r\n\u003Cdiv\u003EAfter completing this module, you will be able to:\u003C\/div\u003E \r\n\u003Cdiv\u003E- Explain what groups and periods are.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Explain the criteria for placing elements in the periodic table.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Provide a suitable name for each group.\u003C\/div\u003E \r\n\u003Cdiv\u003E- Arrange elements according to their atomic number.\u003C\/div\u003E","CONT_DESC_AR":"","BACKING_FILE":null,"FILE_UID":null,"SCORM_COURSE_ID":null,"CONT_SRC":null,"MOD_FILES":null,"FOLDER_NAME":null,"CONTTYPE_ID":"9","ANDROID_PKG":"com.umety.vr.hs200413","TOPIC_ID":"hs200413","IS_PUBLISH":"Y","IS_PUBLIC":"Y","CONT_PRICE":null,"PUBLIC_IMG":"thumb_HS200413.jpg","PUBLIC_BANNER_IMG":"HS200413.jpg","PUBLIC_VIDEO":"pvideo_hs200413.mp4","PUBLIC_VIDEO_URL":"https:\/\/youtu.be\/jnMKcnEqf5o","DIST":null,"SHOW_ON_HOME":"N","CONTROLLER_REQUIRED":"Y","DOMAIN":"3","CONCEPT":"0","STATUS":"A","EXPIRY_DAYS":null,"CREATED_ON":"2017-10-06 04:12:12","CREATED_BY":"0","UPDATED_ON":"2024-10-08 10:27:40","UPDATED_BY":"2","CONT_ORDER":"0","X_ROTATION":null,"Y_ROTATION":null,"Z_ROTATION":null,"BG_COLOR":"0x000000","X_POSITION":null,"Y_POSITION":null,"Z_POSITION":null,"TEMP_DESC":"Overview:\u0026lt;br\u0026gt;\u0026lt;br\u0026gt;The Periodic table is the systematic arrangement of 118 elements in the increasing order of their atomic number. 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