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Chapter 2 Structure and Properties of Organic Molecules

Organic Chemistry , 5 th Edition L. G. Wade, Jr. Chapter 2 Structure and Properties of Organic Molecules. Jo Blackburn Richland College, Dallas, TX Dallas County Community College District ã 2003, Prentice Hall. _. +. +. -. =>. Wave Properties of Electrons.

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Chapter 2 Structure and Properties of Organic Molecules

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  1. Organic Chemistry, 5th EditionL. G. Wade, Jr. Chapter 2Structure and Propertiesof Organic Molecules Jo Blackburn Richland College, Dallas, TX Dallas County Community College District ã 2003,Prentice Hall

  2. _ + + - => Wave Properties of Electrons • Standing wave vibrates in fixed location. • Wave function, , mathematical description of size, shape, orientation • Amplitude may be positive or negative • Node: amplitude is zero Chapter 2

  3. Wave Interactions • Linear combination of atomic orbitals • between different atoms is bond formation • on the same atom is hybridization. • Conservation of orbitals • Waves that are in phase add together.Amplitude increases. • Waves that are out of phase cancel out. => Chapter 2

  4. Sigma Bonding • Electron density lies between the nuclei. • A bond may be formed by s-s, p-p, s-p, or hybridized orbital overlaps. • The bonding MO is lower in energy than the original atomic orbitals. • The antibonding MO is higher in energy than the atomic orbitals. => Chapter 2

  5. H2: s-s overlap => Chapter 2

  6. Cl2: p-p overlap Constructive overlap along the same axis forms a sigma bond. => Chapter 2

  7. HCl: s-p overlap Question: Draw the predicted shape for the bonding molecular orbital and the antibonding molecular orbital of the HCl molecule. Answer: See bottom of page 42 in your text. => Chapter 2

  8. => Pi Bonding • Pi bonds form after sigma bonds. • Sideways overlap of parallel p orbitals. Chapter 2

  9. => Multiple Bonds • A double bond (2 pairs of shared electrons) consists of a sigma bond and a pi bond. • A triple bond (3 pairs of shared electrons) consists of a sigma bond and two pi bonds. Chapter 2

  10. Molecular Shapes • Bond angles cannot be explained with simple s and p orbitals. Use VSEPR theory. • Hybridized orbitals are lower in energy because electron pairs are farther apart. • Hybridization is LCAO within one atom, just prior to bonding. => Chapter 2

  11. => sp Hybrid Orbitals • 2 VSEPR pairs • Linear electron pair geometry • 180° bond angle Chapter 2

  12. => sp2 Hybrid Orbitals • 3 VSEPR pairs • Trigonal planar e- pair geometry • 120° bond angle Chapter 2

  13. => sp3 Hybrid Orbitals • 4 VSEPR pairs • Tetrahedral e- pair geometry • 109.5° bond angle Chapter 2

  14. => Sample Problems • Predict the hybridization, geometry, and bond angle for each atom in the following molecules: • Caution! You must start with a good Lewis structure! • NH2NH2 • CH3-CC-CHO Chapter 2

  15. => Rotation around Bonds • Single bonds freely rotate. • Double bonds cannot rotate unless the bond is broken. Chapter 2

  16. Isomerism • Molecules which have the same molecular formula, but differ in the arrangement of their atoms, are called isomers. • Constitutional (or structural) isomers differ in their bonding sequence. • Stereoisomers differ only in the arrangement of the atoms in space. => Chapter 2

  17. => Structural Isomers Chapter 2

  18. Trans - across Cis - same side No cis-trans isomers possible => Stereoisomers Cis-trans isomers are also called geometric isomers. There must be two different groups on the sp2 carbon. Chapter 2

  19. are due to differences in electronegativity. depend on the amount of charge and distance of separation. In debyes,  = 4.8 x (electron charge) x d(angstroms) => Bond Dipole Moments Chapter 2

  20. => Molecular Dipole Moments • Depend on bond polarity and bond angles. • Vector sum of the bond dipole moments. • Lone pairs of electrons contribute to the dipole moment. Chapter 2

  21. Intermolecular Forces • Strength of attractions between molecules influence m.p., b.p., and solubility; esp. for solids and liquids. • Classification depends on structure. • Dipole-dipole interactions • London dispersions • Hydrogen bonding => Chapter 2

  22. Dipole-Dipole Forces • Between polar molecules • Positive end of one molecule aligns with negative end of another molecule. • Lower energy than repulsions, so net force is attractive. • Larger dipoles cause higher boiling points and higher heats of vaporization. => Chapter 2

  23. Dipole-Dipole => Chapter 2

  24. => London Dispersions • Between nonpolar molecules • Temporary dipole-dipole interactions • Larger atoms are more polarizable. • Branching lowers b.p. because of decreased surface contact between molecules. Chapter 2

  25. Dispersions => Chapter 2

  26. Hydrogen Bonding • Strong dipole-dipole attraction • Organic molecule must have N-H or O-H. • The hydrogen from one molecule is strongly attracted to a lone pair of electrons on the other molecule. • O-H more polar than N-H, so stronger hydrogen bonding => Chapter 2

  27. H Bonds => Chapter 2

  28. => Boiling Points and Intermolecular Forces Chapter 2

  29. Solubility • Like dissolves like • Polar solutes dissolve in polar solvents. • Nonpolar solutes dissolve in nonpolar solvents. • Molecules with similar intermolecular forces will mix freely. => Chapter 2

  30. Ionic Solute with Polar Solvent Hydration releases energy. Entropy increases. => Chapter 2

  31. Ionic Solute withNonpolar Solvent => Chapter 2

  32. Nonpolar Solute withNonpolar Solvent => Chapter 2

  33. Nonpolar Solute with Polar Solvent => Chapter 2

  34. Classes of Compounds • Classification based on functional group • Three broad classes • Hydrocarbons • Compounds containing oxygen • Compounds containing nitrogen => Chapter 2

  35. Hydrocarbons • Alkane: single bonds, sp3 carbons • Cycloalkane: carbons form a ring • Alkene: double bond, sp2 carbons • Cycloalkene: double bond in ring • Alkyne: triple bond, sp carbons • Aromatic: contains a benzene ring => Chapter 2

  36. => Compounds Containing Oxygen • Alcohol: R-OH • Ether: R-O-R' • Aldehyde: RCHO • Ketone: RCOR' Chapter 2

  37. => Carboxylic Acids and Their Derivatives • Carboxylic Acid: RCOOH • Acid Chloride: RCOCl • Ester: RCOOR' • Amide: RCONH2 Chapter 2

  38. => Compounds Containing Nitrogen • Amines: RNH2, RNHR', or R3N • Amides: RCONH2, RCONHR, RCONR2 • Nitrile: RCN Chapter 2

  39. End of Chapter 2 Chapter 2

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