Chem3x11 Lecture 1

This lecture is an overview of isomerism, then some material on stereocentres and what chiral molecules look like in ¹H NMR spectroscopy.

Key concepts

• There are two different kinds of stereoisomers
• Conformations of alkanes governed by sterics and electronics
• Prochiral centres become interesting in a chiral environment

Kinds of Isomerism

Constitutional isomers are the easiest to think about. The molecules are put together differently. Interview each atom in Molecule A in turn by asking "What other atoms are you bonded to?", then do the same for each atom in Molecule B. If the answers you get are different, Molecules A and B are constitutional isomers.

Atoms in stereoisomers would give you the same answer since the atoms are connected to each other the same way, only the positions of the atoms in space changes. The easiest kind of stereoisomers to conceptualize are those around a double bond, i.e. E- and Z- isomers. To interconvert these you'd need to break the double bond, and when a bond needs to be broken we call that configurational isomerism.

Stereocentres are like that too, so enantiomers are configurational isomers.

Stereoisomers you can interconvert without breaking any bonds are both interesting and not. The example below concerns alkanes, which seems silly because we never isolate the alkane isomers under normal conditions - the bond rotation is too easy/fast. But there are some very interesting and important examples of this kind of isomerism, particularly in Nature. Isomers of this kind, where all the atoms are connected to each other the same way, but there is a difference in the 3D arrangement of atoms BUT the isomers can be interconverted without breaking any bonds are called conformational isomers.

An Example of Conformational Isomers - The Rotations of Alkanes

Alkanes (acyclic ones) can rotate about each C-C bond. The different arrangements in space can be interconverted without breaking any bonds, and we call these structures conformational isomers. Typically the interconversion is super-fast and we can't isolate the separate isomers. If it becomes possible to see the separate isomers by e.g. ¹H NMR spectroscopy we sometimes call them rotamers, or, more formally and generally atropisomers.

Different conformational isomers have different arrangements of atoms in space, and these will have different energies, e.g. ethane, below.

Why do these isomers interconvert so quickly? Pretty low barrier to rotation:

For butane there is a greater preference for the conformation where the methyl groups are far apart. Everything's still moving very quickly, but the extended conformation (where the methyl groups are as far from each other as possible) is the lowest in energy. That's why we draw alkane chains as zig-zags, typically.

When butane is in one of its eclipsed conformations, the steric clashes explain the high energies.