12.7 Interpreting Infrared Spectra - Organic Chemistry

12.7 • Interpreting Infrared Spectra

The complete interpretation of an IR spectrum is difficult because most organic molecules have dozens of different bond stretching and bending motions, and thus have dozens of absorptions. On the one hand, this complexity is a problem because it generally limits the laboratory use of IR spectroscopy to pure samples of fairly small molecules—little can be learned from IR spectroscopy about large, complex biomolecules. On the other hand, this complexity is useful because an IR spectrum acts as a unique fingerprint of a compound. In fact, the complex region of the IR spectrum, from 1500 cm^–1 to around 400 cm^–1, is called the fingerprint region. If two samples have identical IR spectra, they are almost certainly identical compounds.

Fortunately, we don’t need to interpret an IR spectrum fully to get useful structural information. Most functional groups have characteristic IR absorption bands that don’t change much from one compound to another. The C=O absorption of a ketone is almost always in the range 1680 to 1750 cm^–1; the O–H absorption of an alcohol is almost always in the range 3400 to 3650 cm^–1; the C=C absorption of an alkene is almost always in the range 1640 to 1680 cm^–1; and so forth. By learning where characteristic functional-group absorptions occur, it’s possible to get structural information from IR spectra. Table 12.1 lists the characteristic IR bands of some common functional groups.

Table 12.1 Characteristic IR Absorptions of Some Functional Groups

Functional Group		Absorption (cm^–1)	Intensity
Alkane	C–H	2850–2960	Medium
Alkene	=C–H	3020–3100	Medium
Alkene	C=C	1640–1680	Medium
Alkyne	$≡C–H$	3300	Strong
Alkyne	$C≡C$	2100–2260	Medium
Alkyl halide	C–Cl	600–800	Strong
Alkyl halide	C–Br	500–600	Strong
Alcohol	O–H	3400–3650	Strong, broad
Alcohol	C–O	1050–1150	Strong
Arene	C–H	3030	Weak
Aromatic ring		1660–2000	Weak
Aromatic ring		1450–1600	Medium
Amine	N–H	3300–3500	Medium
Amine	C–N	1030–1230	Medium
Carbonyl compound	$C═O$	1670–1780	Strong
	Aldehyde	1730	Strong
	Ketone	1715	Strong
	Ester	1735	Strong
	Amide	1690	Strong
	Carboxylic acid	1710	Strong
Carboxylic acid	O–H	2500–3100	Strong, broad
Nitrile	$C≡N$	2210–2260	Medium
Nitro	NO₂	1540	Strong

Look at the IR spectra of hexane, 1-hexene, and 1-hexyne in Figure 12.21 to see an example of how IR spectroscopy can be used. Although all three IR spectra contain many peaks, there are characteristic absorptions of $C═C$ and $C≡C$ functional groups that allow the three compounds to be distinguished. Thus, 1-hexene shows a characteristic $C═C$ absorption at 1660 cm^–1 and a vinylic =C–H absorption at 3100 cm^–1, whereas 1-hexyne has a $C≡C$ absorption at 2100 cm^–1 and a terminal alkyne $≡C - H$ absorption at 3300 cm^–1.

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Figure 12.21 IR spectra of (a) hexane, (b) 1-hexene, and (c) 1-hexyne. Spectra like these are easily obtained from sub-milligram amounts of material in a few minutes using commercially available instruments.

It helps in remembering the position of specific IR absorptions to divide the IR region from 4000 cm^–1 to 400 cm^–1 into four parts, as shown in Figure 12.22.

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Figure 12.22 The four regions of the infrared spectrum: single bonds to hydrogen, triple bonds, double bonds, and fingerprint.

Worked Example 12.4

Distinguishing Isomeric Compounds by IR Spectroscopy

Acetone (CH₃COCH₃) and 2-propen-1-ol ( $H_{2} C═ {CHCH}_{2} OH$ ) are isomers. How could you distinguish them by IR spectroscopy?

Strategy

Identify the functional groups in each molecule, and refer to Table 12.1.

Solution

Acetone has a strong C=O absorption at 1715 cm^–1, while 2-propen-1-ol has an –OH absorption at 3500 cm^–1 and a C=C absorption at 1660 cm^–1.

Problem 12-7

What functional groups might the following molecules contain?

(a)

A compound with a strong absorption at 1710 cm^–1

FAQs

What is the interpretation of the infrared spectra? ›

The interpretation of infrared spectra involves the correlation of absorption bands in the spectrum of an unknown compound with the known absorption frequencies for types of bonds.

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How do you read an infrared spectrum in chemistry? ›

The region from 2000 to 1500 cm^–¹ is where double bonds (C═O, C═N, and C═C) absorb. Carbonyl groups generally absorb in the range 1680 to 1750 cm^–¹, and alkene stretching normally occurs in the narrow range of 1640 to 1680 cm^–¹. The region below 1500 cm^–¹ is the fingerprint portion of the IR spectrum.

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What does IR spectrum tell you about organic molecule? ›

Their IR spectrum displays only C-C and C-H bond vibrations. Of these the most useful are the C-H bands, which appear around 3000 cm-1. Since most organic molecules have such bonds, most organic molecules will display those bands in their spectrum.

What is the principle of IR spectroscopy in organic chemistry? ›

IR spectroscopy detects the absorption of light by a compound, in the IR region of the electromagnetic spectrum. To absorb light a molecule must have a bond within its structure that can exhibit what is referred to as a 'dipole moment' which means electrons within a bond are not shared equally.

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How does IR spectroscopy determine the structure of organic compounds? ›

The major use of IR spectroscopy is in determining the structures of organic compounds. In an IR spectrometer IR radiation in the range 400-4000 cm^-¹ is passed through a sample. The printout of the spectrum then shows which frequencies (wavenumbers) are absorbed.

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What is a strong IR signal at 1700? ›

Carbonyl compounds give a strong signal at 1710 to 1740 cm^-¹, in an IR spectrum, which is closer to 1700 cm^-¹. For simple aldehydes and ketones, the stretching vibration of the carbonyl group has a strong infrared absorption between 1710 and 1740 cm^-¹.

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What does an IR peak at 1450 mean? ›

A strong peak around 1450 cm^-¹ indicates the presence of methylene groups (CH₂), while an additional strong peak about 1375 cm^-¹ is caused by a methyl group (CH₃) (examples 1, 8-10).

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What is normal IR range? ›

Wavelength range and sources

Infrared radiation (IR), also known as thermal radiation, is that band in the electromagnetic radiation spectrum with wavelengths above red visible light between 780 nm and 1 mm. IR is categorized as IR-A (780 nm-1.4 µm), IR-B (1.4-3 µm) and IR-C, also known as far-IR (3 µm-1 mm).

What is the significance of IR spectra? ›

Absorption at specific frequencies is characteristic of certain bonds. Thus, the IR spectrum identifies the various bonds and functional groups within the molecule. In addition, there are also vast libraries of IR spectra that help identify unknown compounds or, at least, place them into certain classes of molecules.

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What is the spectrum of infrared? ›

Infrared radiation (IR), also known as thermal radiation, is that band in the electromagnetic radiation spectrum with wavelengths above red visible light between 780 nm and 1 mm. IR is categorized as IR-A (780 nm-1.4 µm), IR-B (1.4-3 µm) and IR-C, also known as far-IR (3 µm-1 mm).

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What does infrared radiation tell us? ›

Infrared waves have longer wavelengths than visible light and can pass through dense regions of gas and dust in space with less scattering and absorption. Thus, infrared energy can also reveal objects in the universe that cannot be seen in visible light using optical telescopes.

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What does FTIR spectra tell you? ›

Fourier Transform Infrared Spectroscopy, also known as FTIR Analysis or FTIR Spectroscopy, is an analytical technique used to identify organic, polymeric, and, in some cases, inorganic materials. The FTIR analysis method uses infrared light to scan test samples and observe chemical properties.

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