Answer Key for IR assignment Winter 2008

Spectrum 1: 4-Methylcyclohexanone (R4, C2)

Frequency	Assignment
2859-2955	n(CH, sp³)
1717	n(C=O, ketone, sat.)
1378, 1460	d(CH₂, bend)

Spectrum 2: 2,6-Diethylaniline (R3, C2)

Frequency	Assignment
3396, 3479	n(NH₂, prim. amine)
3020-3068	n(CH, sp²)
2872-2966	n(CH, sp³)
1622	d(NH₂, scissoring)
1454, 1622	n(C=C, aromatic)
1378, 1454	d(CH₂, CH₃, bend)
745	1,2,3-trisubst. arene

Spectrum 3: o-Xylene (R1, C3)

Frequency	Assignment
3018-3108	n(CH, sp²)
2860-2971	n(CH, sp³)
1495, 1606	n(C=C, aromatic)
1384, 1455	d(CH₃, bend)
742	oop, ortho-subst. arene

Spectrum 4: 2-Octenoic Acid (R4, C1)

Frequency	Assignment
~2500-3400	n(OH, carboxylic acid)
2878-2932	n(CH, sp³)
1699	n(C=O, conj. acid)
1651	n(C=C, alkene)
1380, 1458	d(CH₂, CH₃, bend)
1285	n(CO, acid)
990	oop, trans alkene

Spectrum 5: Phenylacetaldehyde (R5, C4)

Frequency	Assignment
3427	C=O-overtone
3030-3088	n(CH, sp²)
2900-2950	n(CH, sp³)
2728, 2826	n(CHO, aldehyde)
1724	n(C=O, aldehyde)
1498, 1602	n(C=C, aromatic)
1454	d(CH_2, bend)
701, 751	oop, mono-subst. arene

Spectrum 6: 1,7-Octadiyne (R1, C1)

Frequency	Assignment
3296	n(CH, sp)
2866, 2947	n(CH, sp³)
2118	n(C=C, alkyne)
1446	d(CH₂, bend)
637	d(C=C-H, bend)

Spectrum 7: Butyl crotonate (R5, C3)

Frequency	Assignment
2876-2963	n(CH, sp³)
1725	n(C=O, conj. ester)
1661	n(C=C, alkene)
1381	d(CH₂, CH₃, bend)
1028, 1185	n(COC, ester)
970	oop, trans alkene

Spectrum 8: p-Cresol (R1, C2)

Frequency	Assignment
3100-3600	n(OH, phenol)
3026-3036	n(CH, sp²)
2867-2948	n(CH, sp³)
1514, 1614	n(C=C, aromatic)
1361, 1453	d(CH₃, bend)
1237	n(C-OH, phenol)

Spectrum 9: 2-Methylbutyronitrile (R2, C4)

Frequency	Assignment
3117	n(CH, sp²)
2883-2973	n(CH, sp³)
2241	n(C=N, nitrile)
1388, 1454	d(CH₂, CH₃, bend)

Spectrum 10: Allylsuccinic anhydride (R2, C3)

Frequency	Assignment
3083	n(CH, sp²)
2926, 2985	n(CH, sp³)
1782, 1863	n(C=O, anhydride)
1643	n(C=C, alkene)
1443	d(CH₂, bend)
1069, 1226	n(COC, anhydride)

Note: The designation behind the name is the row and column number the molecule is located in the table.

General comments:

1. The average grade for the assignment is 37 points (out of 40). If you scored around or less than 30 points, I would advise you to see your TA or the instructor to seek some help.

2. One of the most common mistakes was not to analyze the n(C-H) region correctly to determine what type of compound (alkane, alkene, aromatic, or mixed) is present. Just writing "sp³" or "C-H" is not sufficient here.

3. The n(OH) peaks for carboxylic acids and alcohols look very different and can be easily identified by looking at them (see reader). However, in some cases intramolecular hydrogen bonding broadens and shifts (to lower wavenumbers) the peak of an alcohol.

4. Carbonyl peaks can be shifted to lower wavenumbers when the carbonyl function is conjugated to another p-system e.g. double bond or aromatic ring.

5. The presence of two peaks in the carbonyl range (1630-1850 cm^-1) indicates either the presence of an "anhydride type" of function or two different carbonyl functions.

6. Peaks due to amine, alkyne or alcohol functions are very different in appearance. Alkyne peaks (CH stretch) are very sharp and fairly intense due to an "isolated" motion. Amine peaks are usually a little broader and less intense. The presence of two peaks suggests a primary amine (NH₂) while secondary amines show only one peak in this range. Alcohols (OH-stretch) usually show a rounded peak in this area. There is also a difference between amine and amides in terms of width and intensity of the peaks.

8. If the spectrum shows a lot of peaks (independent from their size), the molecule has to have a lot of atoms and also cannot be very symmetric.