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    Lec 11 - Orbital Correction and Plum-Pudding Molecules

    "Lec 11 - Orbital Correction and Plum-Pudding Molecules" Freshman Organic Chemistry (CHEM 125) The lecture opens with tricks ("Z-effective" and "Self Consistent Field") that allow one to correct approximately for the error in using orbitals that is due to electron repulsion. This error is hidden by naming it "correlation energy." Professor McBride introduces molecules by modifying J.J. Thomson's Plum-Pudding model of the atom to rationalize the form of molecular orbitals. There is a close analogy in form between the molecular orbitals of CH4 and NH3 and the atomic orbitals of neon, which has the same number of protons and neutrons. The underlying form due to kinetic energy is distorted by pulling protons out of the Ne nucleus to play the role of H atoms. 00:00 - Chapter 1. Introduction 01:53 - Chapter 2. Correcting for Electron Repulsion when Using Orbitals 15:26 - Chapter 3. Correlation Energy and the Limits of Orbital Theory 30:52 - Chapter 4. Kinetic Energy's Effects on the Shapes of Atomic Orbitals 40:32 - Chapter 5. Moving Nuclei to Distort "Electric Puddings": Case Studies with Methane and Ammonia Complete course materials are available at the Open Yale Courses website: http://open.yale.edu/courses This course was recorded in Fall 2008.

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    Lec 12 - Overlap and Atom-Pair Bonds

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    Lec 1 - How Do You Know?

    Lec 2 - Force Laws, Lewis Structures and Resonance

    Lec 3 - Double Minima, Earnshaw's Theorem and Plum-Puddings

    Lec 4 - Coping with Smallness and Scanning Probe Microscopy

    Lec 5 - X-Ray Diffraction

    Lec 6 - Seeing Bonds by Electron Difference Density

    Lec 7 - Quantum Mechanical Kinetic Energy

    Lec 8 - One-Dimensional Wave Functions

    Lec 9 - Chladni Figures and One-Electron Atoms

    Lec 10 - Reality and the Orbital Approximation

    Lec 12 - Overlap and Atom-Pair Bonds

    Lec 13 - Overlap and Energy-Match

    Lec 14 - Checking Hybridization Theory with XH_3

    Lec 15 - Chemical Reactivity: SOMO, HOMO, and LUMO

    Lec 16 - Recognizing Functional Groups

    Lec 17 - Reaction Analogies and Carbonyl Reactivity

    Lec 18 - Amide, Carboxylic Acid and Alkyl Lithium

    Lec 19 - Oxygen and the Chemical Revolution (Beginning to 1789)

    Lec 20 - Rise of the Atomic Theory (1790-1805)

    Lec 21 - Berzelius to Liebig and Wöhler (1805-1832)

    Lec 22 - Radical and Type Theories (1832-1850)

    Lec 23 - Valence Theory and Constitutional Structure (1858)

    Lec 24 - Determining Chemical Structure by Isomer Counting (1869)

    Lec 25 - Models in 3D Space (1869-1877); Optical Isomers

    Lec 26 - Van't Hoff's Tetrahedral Carbon and Chirality

    Lec 27 - Communicating Molecular Structure in Diagrams and Words

    Lec 28 - Stereochemical Nomenclature; Racemization and Resolution

    Lec 29 - Preparing Single Enantiomers and the Mechanism of Optical Rotation

    Lec 30 - Esomeprazole as an Example of Drug Testing and Usage

    Lec 31 - Preparing Single Enantiomers and Conformational Energy

    Lec 32 - Stereotopicity and Baeyer Strain Theory

    Lec 33 - Conformational Energy and Molecular Mechanics

    Lec 34 - Sharpless Oxidation Catalysts and the Conformation of Cycloalkanes

    Lec 35 - Understanding Molecular Structure and Energy through Standard Bonds

    Lec 36 - Bond Energies, the Boltzmann Factor and Entropy

    Lec Last - Potential Energy Surfaces, Transition State Theory and Reaction Mechanism