While Aromatic and Alkene C-H stretches both occur just over 3000, the C=C aromatic stretches appear between 1600 and 1450, outside the usual range for alkenes which is near 1650. Aromatic C=C stretches are often in pairs, with one at 1600 and one at 1475.
Like substituted alkenes, there are out-of-plane C-H bends between 900 and 690. These result in an overtone/combination band between 2000 and 1667, which is often used to assign how the aromatic molecule is substituted. I assume this because the overtone/combination region is less likely to be obscured by other peaks.
.pdf+-+SumatraPDF_2012-12-08_22-05-00.png)
The shaded boxes in the table above actually correspond to out-of-plane C=C bends.
Below are some spectrum examples:
.pdf+-+SumatraPDF_2012-12-08_22-06-00.png) |
| Infrared spectrum of toluene |
.pdf+-+SumatraPDF_2012-12-08_22-06-07.png) |
| Infrared spectrum of ortho-diethylbenzene |
.pdf+-+SumatraPDF_2012-12-08_22-06-14.png) |
| Infrared spectrum of meta-diethlbenzene |
.pdf+-+SumatraPDF_2012-12-08_22-06-21.png) |
| Infrared spectrum of para-diethylbenzene |
.pdf+-+SumatraPDF_2012-12-08_22-06-25.png) |
| Infrared spectrum of styrene |
The in-plane bending occurs between 1000 - 1300, but these bands are not useful since they overlap with stronger bands in this region.
The original C-H out-of-plane bands can also be used to assign substitution directly in some cases, rather then using the overtone/combination region. It is suggested to use the the 900 - 690 region only for certain substituents:
Reliable substituents:
Alkyl-
Alkoxy-
Halo-
Amino-
Carbonyl-
Unreliable:
Nitro-
Carboxylic acid and derivatives
Sulfonic acids and derivatives
Monosubstituted: Always gives a strong band at 690, but in a halocarbon solvent this may be obscured by a C-X stretch. A second strong band usually appears at 750.
Orthosubstituted: One strong band near 750.
Metasubstituted: One band near 690 and one near 780. A third band is often found at 880.
Parasubstituted: One strong band between 800 and 850.
This is great! Thanks!
ReplyDeleteHow do EWG and EDG's affect the position (wave number) of the aromatic C-C bonds?
ReplyDeletethanks dude
ReplyDeleteCan you label Infrared spectrum for Benzene please?
ReplyDeletecant you just subtract c=c and c=c-h?
DeleteWhat will that do?
Deletecan you please share the exact reference? please.
ReplyDeletehttps://drive.google.com/open?id=0B43zb8GUN7q2NFctdm9KajVTZ0E
Deletethank you so much.. can you recommend me some books for IR spectroscopy (for aromatic hydrocarbons)
DeleteHi there, nice post.
ReplyDeleteI found this paper "Kross, R. D., Fassel, V. A., & Margoshes, M. (1956). The Infrared Spectra of Aromatic Compounds. II. Evidence Concerning the Interaction of π-Electrons and σ-Bond Orbitals in C-H Out-of-plane Bending Vibrations1. Journal of the American Chemical Society, 78(7), 1332–1335. doi:10.1021/ja01588a019".
The experimental data show that Nitrobenzene has a strong band at about 710 cm-1. Therefore, Nitro- should be considered as a reliable substituent with pronounced bands between 900 an 690 cm-1.