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Week
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Topics
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Teaching and Learning Methods and Techniques
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Study Materials
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1. Week
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MOLECULAR ORBITAL THEORY (MOT): Interaction of atomic orbitals, Molecular orbital energy diagrams of A2, AB, AB2, AB3 and AB4 type molecules.
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Lecture; Question Answer; Discussion
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Homework
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2. Week
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COORDINATION CHEMISTRY: Basic consept of coordination chemistry, Coordination compounds, Ligands, Developments in coordination chemistry.
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Lecture; Question Answer; Discussion
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Homework
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3. Week
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NOMENCLATURE OF COORDINATION COMPOUNDS.
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Lecture; Question Answer; Discussion
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Homework
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4. Week
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ISOMERISM IN COORDINATION COMPOUNDS: Structural isomerism (Ligand isomerism, Ionization isomerism, Hydrate (solvent) isomerism, Coordination isomerism, Linkage isomerism, Polymerization isomerism) and Stereoisomerism (Diastereoisomerism (Geometrical (c-s-/trans-) isomerism, Conformation isomerism), Optical isomerism).
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Lecture; Question Answer; Discussion
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Homework
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5. Week
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18 ELECTRON RULE [EFFECTIVE ATOMIC NUMBER (EAN) RULE]: Werner complexes, Carbonyl complexes (metal carbonyls), Nitrosil complexes, Dinitrogen complexes, Dioxygen complexes.
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Lecture; Question Answer; Discussion
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Homework
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6. Week
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18 ELECTRON RULE [EFFECTIVE ATOMIC NUMBER (EAN) RULE]: Olefin complexes, Alkyne complexes, Arene complexes, Cyclopentadienyl complexes
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Lecture; Question Answer; Discussion
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Homework
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7. Week
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VALANCE BOND THEORY: Linear complexes, Tetrahedral complexes, Square planar complexes, Octahedral complexes.
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Lecture; Question Answer; Discussion
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Homework
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8. Week
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CRYSTAL FIELD THEORY (CFT): Basic concept of CFT, The orbital splitting diagrams for octahedral, tetrahedral and square planar complexes.
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Lecture; Question Answer; Discussion
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Homework
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9. Week
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CRYSTAL FIELD THEORY (CFT): Calculation of crystal field stabilization energy or crystal field splitting energy (CFSE) in octahedral, tetrahedral and square planner complexes, The orbital splitting diagrams for other complexes.
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Lecture; Question Answer; Discussion
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Homework
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10. Week
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CRYSTAL FIELD THEORY (CFT): Jahn-Teller effect (tetragonal distortion), 10Dq parameter and electronic spectra, Spectrochemical series, Factors affecting CFSE, Effects of crystal field splitting.
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Lecture; Question Answer; Discussion
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Homework
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11. Week
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MOLECULAR ORBITAL THEORY IN COORDINATION COMPOUNDS: Octahedral complexes (σ-Bonding, п-Bonding), Tetrahedral complexes and Square planar complexes.
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Lecture; Question Answer; Discussion
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Homework
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12. Week
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SOLIDS: Classifications of solids and crystals, Unit cell, clarifications of crystal structures using X-ray crystallography, Ionic solids (radii ratio r + / r-, crystal defects, stacking in solids, AX (ZnS, NaCl, CsCl) and AX2 (CaF2, TiO2, SiO2) type compounds, layered structures (CdI2, CdCl2, NiAs), structures containing polyatomic ions, other lattices.
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Lecture; Question Answer; Discussion
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Homework
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13. Week
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SOLIDS: Lattice energy, Born-Haber cycle, Applications of lattice energy (determination of electron, ion and proton affinities and finding enthalpies of disproportionation and formation).
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Lecture; Question Answer; Discussion
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Homework
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14. Week
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METALS: Metallic character and physical properties of metals (electrical and thermal conductivity of metals, brightness of metals, thermoionic and photoelectric phenomena in metals, crystal structure of metals, ability to be beaten and withdrawn properties in metals, metal alloying feature, Theories related to bonding in metals (free electron theory, valence bond theory, molecular orbital theory), conductors, semiconductors and insulators, super conductors.
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Lecture; Question Answer; Discussion
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Homework
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