{"id":1499,"date":"2021-10-05T11:07:19","date_gmt":"2021-10-05T11:07:19","guid":{"rendered":"https:\/\/webmockup.in\/virtualize\/?page_id=1499"},"modified":"2021-10-05T11:07:19","modified_gmt":"2021-10-05T11:07:19","slug":"chemistry","status":"publish","type":"page","link":"https:\/\/virtualize.org.in\/index.php\/chemistry\/","title":{"rendered":"Chemistry"},"content":{"rendered":"

[vc_row disable_element=”yes” css=”.vc_custom_1633322718735{margin-top: 200px !important;padding-right: 100px !important;padding-left: 100px !important;}”][vc_column width=”2\/3″][vc_custom_heading text=”Mel Science VR” font_container=”tag:h1|text_align:left” use_theme_fonts=”yes”][vc_column_text css=”.vc_custom_1631940688661{margin-top: 0px !important;margin-right: 0px !important;margin-bottom: 0px !important;margin-left: 0px !important;border-top-width: 0px !important;border-right-width: 0px !important;border-bottom-width: 0px !important;border-left-width: 0px !important;padding-top: 0px !important;padding-right: 0px !important;padding-bottom: 0px !important;padding-left: 0px !important;}”]Mel Chem offers a comprehensive VR library of complex chemistry concepts in an easy to understand virtual content format. The Chemistry VR lessons from Mel Science is quite beneficial for students. Up until now, students were able to see atoms, molecules, and the bonding between them only in textbooks and on blackboards. But now they can see them in the virtual world and also figure out how they are arranged in different elements such as in salt, graphite, and diamond.<\/p>\n

Once students start experiencing the smallest to biggest parts of matter through virtual screens, they will be more interested in going deeper into the subject and learn concepts wholeheartedly. As of now, we have seen a 97-99% increment in the interest of students by learning using modern immersive technologies.
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Chemistry :<\/strong><\/h3>\n

[\/vc_column_text][\/vc_column_inner][\/vc_row_inner][vc_row_inner][vc_column_inner width=”1\/2″][vc_column_text]Acetaldehyde
\nAcetic Acid
\nAcetylene
\nAdenine
\nAdenosine Triphosphate (ATP)
\nAluminium
\nAmmonia (Azane)
\nAnion Creation
\nAutoprotolysis of Water
\nBenzene
\nBenzopyrene
\nBohr Model of the Atom of Helium
\nBohr Model of the Atom of Oxygen
\nBoric Acid
\nBurning of Natural Gas
\nButa-1,3-Diene
\nButyric Acid
\nCalcium
\nCalcium Carbonate
\nCalcium Hexaboride
\nCalcium Oxide
\nCalcium Sulfate and Gypsum
\nCarbon Dioxide
\nCarbon Tetrachloride
\nCation Creation
\nChloric Acid
\nChrome
\nCitric Acid
\nCombining Substances
\nCopper
\nCopper Sulphate and Bluestone
\nCyclohexane \u2013 Boat
\nCytosine
\nDecomposition of Substances
\nDensity
\nD-Glucose
\nDiastereomers
\nDNA
\nDNA Base Complementarity C\u2261G in DNA
\nEclipsed and Staggered Conformation of Ethane
\nElectron Density Distribution of Ethane Molecule Single Bond
\nElectron Density Distribution of Ethyne Molecule Triple Bond
\nEnantiomers
\nEther
\nEthylene
\nFace-Centered Cubic Cell
\nFluorine and Fluorine Molecule
\nFormaldehyde
\nFormation of Covalent Bond within CO\u2082 Molecule
\nFormation of Covalent Bond within Hydrogen Chloride Molecule
\nFormation of Covalent Bonds in H\u2082O
\nFormation of Covalent Bonds within H\u2082 Molecule
\nFormation of Ionic Bonds in CaCl\u2082
\nFormic Acid
\nGermanium
\nGlycin
\nGraphite
\nGunpowder
\nHelium and Helium Atoms
\nHydrochloric Acid (Hydrogen Chloride)
\nHydrogen and Hydrogen Molecule
\nHydrogen Isotopes
\nHydrogen Sulfide
\nIodine and Iodine Molecule
\nIsoprene
\nLactose
\nLithium
\nMagnesium
\nMaltose
\nMelting Point
\nMethane
\nMoisture Coating around the Ammonium Cation
\nMoisture Coating around the Sodium Cation
\nNADP\u207a
\nNaphthalene
\nNitric Acid
\nNitrogen and Nitrogen Molecule
\nNitrogen Dioxide \u2013 Monomer
\nNucleophilic Substitution Type 2 (SN2)
\nOleic Acid
\nOrbital Hybridization \u2013 sp\u00b2
\nOxalic Acid
\nOxidising Properties of Chlorate
\nOxidizing Abilities of Nitrates
\nOzone
\nParticles of Gaseous Substances
\nParticles of Solid Substances
\nPeriodic Table
\nPeroxymonosulfuric Acid
\nPhase Transition \u2013 Evaporation
\nPhase Transition \u2013 Melting
\nPhenol
\nPhosphodiester Bond in Nucleic Acid Molecule
\nPhosphorus and Its Modification
\nPhosphorus Trioxide
\nPolarity of Water Molecule
\nPotassium Chlorate
\nPotassium Hydroxide
\nPotassium Perchlorate
\nPreparation of Oxygen from Hydrogen Peroxide
\nProperties of Liquid Oxygen
\nPyrimidine
\nPyrophoricity of White Phosphorus
\nQuantum Mechanical Model of Hydrogen Atom
\nQuicksilver (Mercury)
\nReaction of Magnesium with Dry Ice
\nReaction of Phosphorus with Chlorate
\nRNA
\nRNA Base Complementarity C\u2261G in RNA
\nSalt Dissolving in Water
\nSilicon Dioxide
\nSimple Cubic Unit Cell
\nSodium Bicarbonate
\nSodium Chloride
\nSodium Nitrate
\nStructure of the Atom
\nSucrose
\nSulfur Dioxide
\nSulfur Trioxide \u2013 Trimer
\nSylvite
\ntert-Butyl Bromide
\nThymine
\nToluene
\nTrinitrotoluene
\nUrea
\nVitamin A\u2081
\nVitamin C
\nWater
\nWater Solution of Hydrochloric Acid
\nZinc[\/vc_column_text][\/vc_column_inner][vc_column_inner width=”1\/2″][vc_column_text]Acetanhydride
\nAcetone
\nAcetylsalicylic Acid
\nAdenosine Diphosphate (ADP)
\nAlanine
\nAmmonia
\nAniline
\nArsenic
\nBenzaldehyde
\nBenzoic Acid
\nBody-Centered Cubic Cell
\nBohr Model of the Atom of Hydrogen
\nBoiling Point
\nBromine and Bromine Molecule
\nBurning Sulfur
\nButane
\nCalcite
\nCalcium Bicarbonate
\nCalcium Fluoride
\nCalcium Hydroxide
\nCalcium Oxide
\nCarbon and its Modifications
\nCarbon Monoxide
\nCarbonic Acid
\nChemical Replacement
\nChlorine and Chlorine Molecule
\nCis\/Trans Isomerism
\nCobalt
\nCombustion of Ammonia
\nCopper Ore – Zoom
\nCovalent radius
\nCyclohexane \u2013 Chair
\nDecomposition of Ammonium Dichromate
\nDehydrating Properties of Concentrated Sulfuric Acid
\nD-Fructose
\nDiamond
\nDiborane
\nDNA Base Complementarity A=T in DNA
\nD-Ribose
\nElectron affinity
\nElectron Density Distribution of Ethene Molecule Double Bond
\nElectronegativity
\nEthane
\nEthyl Alcohol
\nEthylene Glycol
\nFirst Ionization Energy
\nFluorite
\nFormation of Covalent Bond within Chlorine Molecule
\nFormation of Covalent Bond within Fluorine Molecule
\nFormation of Covalent Bond within Nitrogen Molecule
\nFormation of Covalent Bonds with O\u2082 Molecules
\nFormation of Hydrogen Bonds with Water Molecules
\nFormation of Ionic Bonds in NaCl
\nFullerene
\nGlycerol
\nGold
\nGuanine
\nHalite
\nHydrazine
\nHydrofluoric Acid (Hydrogen Fluoride)
\nHydrogen Explosion
\nHydrogen Peroxide
\nIce
\nIron
\nLactic Acid
\nLead
\nL-Monosodium Glutamate
\nMagnetite
\nManufacture of Brass
\nMesomer
\nMethyl Alcohol
\nMoisture Coating around the Chloride Anion
\nMonosilan
\nNADPH
\nNickel
\nNitrobenzene
\nNitrogen Dioxide \u2013 Dimer
\nNitrogen Triiodide
\nNucleosides and Nucleotides
\nOrbital Hybridization \u2013 sp
\nOrbital Hybridization \u2013 sp\u00b3
\nOxidative Capacity of Perchlorate
\nOxidising Properties of Hydrogen Peroxide
\nOxygen and Oxygen Molecule
\nPalmitic Acid
\nParticles of Liquids
\nPerchloric Acid
\nPeroxymonosulfuric Acid
\nPhase Transition \u2013 Condensation
\nPhase Transition \u2013 Freezing
\nPhase Transition \u2013 Sublimation and Desublimation
\nPhosphine
\nPhosphoric Acid
\nPhosphorus Pentoxide
\nPlatinum
\nPotassium
\nPotassium Chloride
\nPotassium Nitrate
\nPotassium Permanganate
\nPropane
\nPurin
\nPyrite
\nQuantum Mechanical Model of Helium Atom
\nQuartz
\nReaction of Copper with Nitric Acid
\nReaction of Permanganate with Glycerol
\nRelative Atomic Weight
\nRNA Base Complementarity A=U in RNA
\nRotation of the Electron around Hydrogen Nucleus
\nSilicon
\nSilver
\nSodium
\nSodium Carbonate
\nSodium Hydroxide
\nStearic Acid
\nStyrene
\nSulfur and Sulfur Molecules S\u2082 and S\u2088
\nSulfur Trioxide \u2013 Monomer
\nSulfuric Acid
\ntert-Butyl Alcohol
\nTetrafluoroethylene
\nTitanium
\nTrichlorofluoromethane
\nUracil
\nVinyl Chloride
\nVitamin B\u2081
\nVitamin D\u2082
\nWater Solution of Ammonia (Ammonium Hydroxide)
\nWater Solution of Sodium Hydroxide[\/vc_column_text][\/vc_column_inner][\/vc_row_inner][\/vc_column][\/vc_row]<\/p>\n","protected":false},"excerpt":{"rendered":"

[vc_row disable_element=”yes” css=”.vc_custom_1633322718735{margin-top: 200px !important;padding-right: 100px !important;padding-left: 100px !important;}”][vc_column width=”2\/3″][vc_custom_heading text=”Mel Science VR” font_container=”tag:h1|text_align:left” use_theme_fonts=”yes”][vc_column_text css=”.vc_custom_1631940688661{margin-top: 0px !important;margin-right: 0px !important;margin-bottom: 0px !important;margin-left: 0px !important;border-top-width: 0px !important;border-right-width: 0px !important;border-bottom-width: 0px !important;border-left-width: 0px !important;padding-top: 0px !important;padding-right: 0px !important;padding-bottom: 0px !important;padding-left: 0px !important;}”]Mel Chem offers a comprehensive VR library of complex chemistry concepts in an easy to understand […]<\/p>\n","protected":false},"author":1,"featured_media":0,"parent":0,"menu_order":0,"comment_status":"closed","ping_status":"closed","template":"page-templates\/pages.php","meta":{"footnotes":""},"class_list":["post-1499","page","type-page","status-publish","hentry"],"_links":{"self":[{"href":"https:\/\/virtualize.org.in\/index.php\/wp-json\/wp\/v2\/pages\/1499","targetHints":{"allow":["GET"]}}],"collection":[{"href":"https:\/\/virtualize.org.in\/index.php\/wp-json\/wp\/v2\/pages"}],"about":[{"href":"https:\/\/virtualize.org.in\/index.php\/wp-json\/wp\/v2\/types\/page"}],"author":[{"embeddable":true,"href":"https:\/\/virtualize.org.in\/index.php\/wp-json\/wp\/v2\/users\/1"}],"replies":[{"embeddable":true,"href":"https:\/\/virtualize.org.in\/index.php\/wp-json\/wp\/v2\/comments?post=1499"}],"version-history":[{"count":1,"href":"https:\/\/virtualize.org.in\/index.php\/wp-json\/wp\/v2\/pages\/1499\/revisions"}],"predecessor-version":[{"id":1500,"href":"https:\/\/virtualize.org.in\/index.php\/wp-json\/wp\/v2\/pages\/1499\/revisions\/1500"}],"wp:attachment":[{"href":"https:\/\/virtualize.org.in\/index.php\/wp-json\/wp\/v2\/media?parent=1499"}],"curies":[{"name":"wp","href":"https:\/\/api.w.org\/{rel}","templated":true}]}}