The Chemistry of Rotational Isomers

1 Introduction.- 1.1 The "Free Rotation" Concept.- 1.2 Recognition of Rotational Isomers.- 1.3 Atropisomers.- 1.4 Isolation of Rotational Isomers.- 1.4.1 Factors Affecting Barrier Heights.- 1.4.2 Triptycene Derivatives.- 1.4.3 9-Arylfluorenes.- 1.5 Concepts That Need Modification.- 1.5.1 Are There Dextrorotatory and Levorotatory Groups?.- 1.5.2 Reactivity of Rotational Isomers.- 1.6 References.- 2 Rotamer Populations.- 2.1 Estimation of Rotamer Populations.- 2.1.1 Vibration Spectroscopy.- 2.1.2 Nuclear Magnetic Resonance Spectroscopy.- 2.2 Factors That Affect Rotamer Populations.- 2.3 Information on Molecular Interactions Obtained from Rotamer Populations.- 2.3.1 Triptycenes.- 2.3.1.1 Long-Range Coupling in NMR Spectra.- 2.3.1.2 Steric Repulsion.- 2.3.1.3 n-? Interactions.- 2.3.1.4 n-? Interactions.- 2.3.1.5 Hydrogen Bonding Involving a Methyl Group.- 2.3.2 9-Arylfluorenes.- 2.3.2.1 XH-? Interactions.- 2.3.2.2 ?-? Interactions.- 2.4 References.- 3 Barriers to Rotation.- 3.1 Estimation of Barriers to Rotation.- 3.1.1 Coalescence Method.- 3.1.2 Line Shape Analysis.- 3.1.3 Saturation Transfer.- 3.1.4 The 2D-NMR Spectroscopy.- 3.1.5 Classical Kinetics.- 3.1.6 Reliability of the Data.- 3.2 High Barriers to Rotation in the 9-Arylfluorene Series.- 3.2.1 Isolation of Rotational Isomers.- 3.2.2 Factors Affecting the Rotational Barriers.- 3.2.2.1 Effects of the Steric Size of the Substituents.- 3.2.2.2 Ground State Destabilization.- 3.2.2.3 Ground State Stabilization.- 3.2.2.4 Solvent Effects.- 3.3 High Barriers to Rotation in 9-Substituted Triptycene Series.- 3.3.1 Triptycenes Carrying a 9-tert-Alkyl Substituent.- 3.3.2 Triptycenes Carrying a 9-sec-Alkyl Substituent.- 3.3.3 Triptycenes Carrying a 9-prim-Alkyl Substituent.- 3.3.4 Atropisomers About a Carbon-to-Heteroatom Bond.- 3.4 High Barriers to Rotation in Miscellaneous Compounds.- 3.4.1 Atropisomerism About an sp3-sp3 Bond.- 3.4.2 Atropisomerism About an sp3-sp2 Bond.- 3.5 References.- 4 Reactivity of Rotational