CHEM 344

1. CHEM 344 Spectroscopy of Organic Compounds Lecture 3 11th and 12th September 2007

2. Review of Lecture 2 • Spin-spin splitting leads to multiplicity in NMR spectra • The size of the splitting between two hydrogen atoms is the coupling constant, J (measured inHz). • n+1 rule - doublet, triplet, quartet…..Pascal’s triangle • Infrared radiation excites molecular vibrations • IR bands depend on bond type, strength etc. • IR spectroscopy good for functional group assignment

3. NMR: Exceptions to the n+1 Rule • The n+1 rule does not apply when a set of equivalent protons is split by two or more other non-equivalent sets with different coupling constants. • The n+1 rule does not apply to spectra in which the chemical shift difference between two sets of protons is not much larger than the coupling constant (e.g. butane, hexane). • These are termed “second-order” spectra and usually have to be simulated. The signals typically appear to be very poorly resolved. • You are very unlikely to encounter 2nd order spectra in CHEM 344

8. NMR: Some Specific Functional Group Characteristics • O-H and N-H protons often show broad peaks with no resolved splitting (acidic exchange broadening), and their chemical shifts vary greatly. • An aldehyde C-H is strongly deshielded (d = 9-10 ppm) and coupling to alkyl protons on adjacent carbon atom is small (i.e. J is very low). • Carboxylic acid O-H is very strongly deshielded. (d = 10-12 ppm)

9. In this example, the O-H proton (labeled c) gives a sharp signal but does not influence the splitting pattern of the Hb protons.

10. NMR: Some Specific Functional Group Characteristics • Cis and trans protons on alkenes usually show strong coupling, but geminal protons on alkenes show little or no resolved coupling. • Jcis≈ 8 Hz Jtrans ≈ 15 Hz Jgem ≈ 0 Hz • Ortho splitting on aromatic rings is often resolved, but meta and para splitting is not. • Jo≈ 8 Hz Jm ≈ 4 Hz Jp ≈ 0 - 2 Hz

17. NMR: Mixtures of Compounds • Unlike most textbook examples, “real world” NMR samples usually contain mixtures of compounds. • It is common to see extra signals due to impurities. • Impurities can be side products, un-reacted starting materials, solvent contaminants etc. • In some cases it is useful (or necessary) to analyze mixtures that contain comparable amounts of two or more compounds.

18. NMR: Mixtures of compounds Synthesis of ethyl acetate by Fischer Esterification (you will do this in CHEM 344). At equilibrium, all 4 components are present. Remove H2O by drying agent, remove RCO2H by neutralization. Can analyze NMR spectrum of mixture to determine extent of reaction.

21. Unknown A(Figure 14.27 Solomons 8th ed.) • Formula = C9H12 • IHD = 4 • IR shows no medium or strong bands above 1650 cm-1 except C-H stretching bands around 3,000 cm-1 • 1H NMR d: 1.26 (d, 6H), 2.90 (sept., 1H), 7.1-7.5 (m, 5H)

23. Unknown B(Figure 14.27 Solomons 8th ed.) • Formula = C8H11N • IHD = 4 • IR shows two medium peaks between 3300 and 3500 cm-1 . No other medium or strong bands above 1650 cm-1 except C-H stretching bands around 3,000 cm-1 • 1H NMR d: 1.4 (d, 3H), 1.7 (s, br, 2H), 4.1(quart., 1H), 7.2-7.4 (m, 5H)

25. Unknown C(Figure 14.27 Solomons 8th ed.) • Formula = C9 H10 • IHD = 5 • IR shows no medium or strong bands above 1650 cm-1 except C-H stretching bands around 3,000 cm-1 • 1H NMR d: 2.05 (pent., 2H), 2.90 (trip., 4H), 7.1-7.3 (m, 4H)