Spectrochemistry

Spectrochemistry is the application of spectroscopy in several fields of chemistry. It includes analysis of spectra in chemical terms, and use of spectra to derive the structure of chemical compounds, and also to qualitatively and quantitively analyze their presence in the sample. It is a method of chemical analysis that relies on the measurement of wavelengths and intensity of electromagnetic radiation.^[1]

^[2] Dichloromethane IR Spectrum

History[]

Isaac Newton - English mathematician and Physicist

Joseph Von Fraunhofer- Bavarian Physicist

Gustav Kirchhoff - German Physicist

Thomas Young - British Polymath

It was not until 1666 that Isaac Newton showed that white lights from the sun could be dissipated into a continuous series of colors. So Newton introduced the concept which he called spectrum to describe this phenomenon. He used a small aperture to define the beam of light, a lens to collimate it, a glass prism to disperse it, and a screen to display the resulting spectrum. Newton's analysis of light was the beginning of the science of spectroscopy. Later, It became clear that the Sun's radiation might have components outside the visible portion of the spectrum. In 1800 William Hershel showed that the sun's radiation extended into infrared, and in 1801 John Wilhelm Ritter also made a similar observation in the ultraviolet. Joseph Von Fraunhofer extended Newton's discovery by observing the sun's spectrum when sufficiently dispersed was blocked by a fine dark lines now known as Fraunhofer lines. Fraunhofer also developed diffracting grating, which disperses the lights in much the same way as does a glass prism but with some advantages. the grating applied interference of lights to produce diffraction provides a direct measuring of wavelengths of diffracted beams. So by extending Thomas Young's study which demonstrated that a light beam passes slit emerges in patterns of light and dark edges Fraunhofer was able to directly measure the wavelengths of spectral lines. However, despite his enormous achievements, Fraunhofer was unable to understand the origins of the special line in which he observed. It was not until 33 years after his passing that Gustav Kirchhoff established that each element and compound has its unique spectrum and that by studying the spectrum of an unknown source, one could determine its chemical compositions, and with these advancements, spectroscopy became a truly scientific method of analyzing the structures of chemical compounds. Therefore, by recognizing that each atom and molecule has its spectrum Kirchhoff and Robert Bunsen established spectroscopy as a scientific tool for probing atomic and molecular structures and founded the field of spectrochemical analysis for analyzing the composition of materials.^[3]

Robert Bunsen - German Chemist

IR Spectra Tables & Charts[]

IR Spectrum Table by Frequency^[4]

Frequency Range	Absorption (cm⁻¹)	Appearance	Group	Compound Class	Comments
4000–3000 cm⁻¹	3700-3584	medium, sharp	O-H stretching	alcohol	free
	3550-3200	strong, broad	O-H stretching	alcohol	intermolecular bonded
	3500	medium	N-H stretching	primary amine
	3400
	3400-3300	medium	N-H stretching	aliphatic primary amine
	3330-3250
	3350-3310	medium	N-H stretching	secondary amine
	3300-2500	strong, broad	O-H stretching	carboxylic acid	usually centered on 3000 cm⁻¹
	3200-2700	weak, broad	O-H stretching	alcohol	intramolecular bonded
	3000-2800	strong, broad	N-H stretching	amine salt
3000–2500 cm⁻¹
3000–2500 cm⁻¹	3333-3267	strong, sharp	C-H stretching	alkyne
	3100-3000	medium	C-H stretching	alkene
	3000-2840	medium	C-H stretching	alkane
	2830-2695	medium	C-H stretching	aldehyde	doublet
	2600-2550	weak	S-H stretching	thiol
2400–2000 cm⁻¹
2400–2000 cm⁻¹	2349	strong	O=C=O stretching	carbon dioxide
	2275-2250	strong, broad	N=C=O stretching	isocyanate
	2260-2222	weak	CΞN stretching	nitrile
	2260-2190	weak	CΞC stretching	alkyne	disubstituted
	2175-2140	strong	S-CΞN stretching	thiocyanate
	2160-2120	strong	N=N=N stretching	azide
	2150		C=C=O stretching	ketene
	2145-2120	strong	N=C=N stretching	carbodiimide
	2140-2100	weak	CΞC stretching	alkyne	monosubstituted
	2140-1990	strong	N=C=S stretching	isothiocyanate
	2000-1900	medium	C=C=C stretching	allene
	2000		C=C=N stretching	ketenimine
2000–1650 cm⁻¹
2000–1650 cm⁻¹	2000-1650	weak	C-H bending	aromatic compound	overtone

	1870-1540
	1818	strong	C=O stretching	anhydride
	1750
	1815-1785	strong	C=O stretching	acid halide
	1800-1770	strong	C=O stretching	conjugated acid halide
	1775	strong	C=O stretching	conjugated anhydride
	1720
	1770-1780	strong	C=O stretching	vinyl / phenyl ester
	1760	strong	C=O stretching	carboxylic acid	monomer
	1750-1735	strong	C=O stretching	esters	6-membered lactone
	1750-1735	strong	C=O stretching	δ-lactone	γ: 1770
	1745	strong	C=O stretching	cyclopentanone
	1740-1720	strong	C=O stretching	aldehyde
	1730-1715	strong	C=O stretching	α,β-unsaturated ester	or formates
	1725-1705	strong	C=O stretching	aliphatic ketone	or cyclohexanone or cyclopentenone
	1720-1706	strong	C=O stretching	carboxylic acid	dimer
	1710-1680	strong	C=O stretching	conjugated acid	dimer
	1710-1685	strong	C=O stretching	conjugated aldehyde
	1690	strong	C=O stretching	primary amide	free (associated: 1650)
	1690-1640	medium	C=N stretching	imine / oxime
	1685-1666	strong	C=O stretching	conjugated ketone
	1680	strong	C=O stretching	secondary amide	free (associated: 1640)
	1680	strong	C=O stretching	tertiary amide	free (associated: 1630)
	1650	strong	C=O stretching	δ-lactam	γ: 1750-1700 β: 1760-1730
1670–1600 cm⁻¹
1670–1600 cm⁻¹	1678-1668	weak	C=C stretching	alkene	disubstituted (trans)
	1675-1665	weak	C=C stretching	alkene	trisubstituted
	1675-1665	weak	C=C stretching	alkene	tetrasubstituted
	1662-1626	medium	C=C stretching	alkene	disubstituted (cis)
	1658-1648	medium	C=C stretching	alkene	vinylidene
	1650-1600	medium	C=C stretching	conjugated alkene
	1650-1580	medium	N-H bending	amine
	1650-1566	medium	C=C stretching	cyclic alkene
	1648-1638	strong	C=C stretching	alkene	monosubstituted
	1620-1610	strong	C=C stretching	α,β-unsaturated ketone
1600–1300 cm⁻¹
1600–1300 cm⁻¹	1550-1500	strong	N-O stretching	nitro compound
	1372-1290
	1465	medium	C-H bending	alkane	methylene group
	1450	medium	C-H bending	alkane	methyl group
	1375
	1390-1380	medium	C-H bending	aldehyde
	1385-1380	medium	C-H bending	alkane	gem dimethyl
	1370-1365
1400–1000 cm⁻¹
1400–1000 cm⁻¹	1440-1395	medium	O-H bending	carboxylic acid
	1420-1330	medium	O-H bending	alcohol
	1415-1380	strong	S=O stretching	sulfate
	1200-1185
	1410-1380	strong	S=O stretching	sulfonyl chloride
	1204-1177
	1400-1000	strong	C-F stretching	fluoro compound
	1390-1310	medium	O-H bending	phenol
	1372-1335	strong	S=O stretching	sulfonate
	1195-1168
	1370-1335	strong	S=O stretching	sulfonamide
	1170-1155
	1350-1342	strong	S=O stretching	sulfonic acid	anhydrous
	1165-1150				hydrate: 1230-1120
	1350-1300	strong	S=O stretching	sulfone
	1160-1120
	1342-1266	strong	C-N stretching	aromatic amine
	1310-1250	strong	C-O stretching	aromatic ester
	1275-1200	strong	C-O stretching	alkyl aryl ether
	1075-1020
	1250-1020	medium	C-N stretching	amine
	1225-1200	strong	C-O stretching	vinyl ether
	1075-1020
	1210-1163	strong	C-O stretching	ester
	1205-1124	strong	C-O stretching	tertiary alcohol
	1150-1085	strong	C-O stretching	aliphatic ether
	1124-1087	strong	C-O stretching	secondary alcohol
	1085-1050	strong	C-O stretching	primary alcohol
	1070-1030	strong	S=O stretching	sulfoxide
	1050-1040	strong, broad	CO-O-CO stretching	anhydride
1000–650 cm⁻¹
1000–650 cm⁻¹	995-985	strong	C=C bending	alkene	monosubstituted
	915-905
	980-960	strong	C=C bending	alkene	disubstituted (trans)
	895-885	strong	C=C bending	alkene	vinylidene
	850-550	strong	C-Cl stretching	halo compound
	840-790	medium	C=C bending	alkene	trisubstituted
	730-665	strong	C=C bending	alkene	disubstituted (cis)
	690-515	strong	C-Br stretching	halo compound
	600-500	strong	C-I stretching	halo compound
900–700 cm⁻¹
900–700 cm⁻¹	880 ± 20	strong	C-H bending	1,2,4-trisubstituted
	810 ± 20
	880 ± 20	strong	C-H bending	1,3-disubstituted
	780 ± 20
	(700 ± 20)
	810 ± 20	strong	C-H bending	1,4-disubstituted or
				1,2,3,4-tetrasubstituted
	780 ± 20	strong	C-H bending	1,2,3-trisubstituted
	(700 ± 20)
	755 ± 20	strong	C-H bending	1,2-disubstituted
	750 ± 20	strong	C-H bending	monosubstituted
	700 ± 20			benzene derivative

IR Spectra Table by Compound Class^[5]

Compound Class	Group	Absorption (cm⁻¹)	Appearance	Comments
acid halide	C=O stretching	1815-1785	strong
alcohols	O-H stretching	3700-3584	medium, sharp	free
	O-H stretching	3550-3200	strong, broad	intermolecular bonded
	O-H stretching	3200-2700	weak, broad	intramolecular bonded
	O-H bending	1420-1330	medium
aldehyde	C-H stretching	2830-2695	medium	doublet
	C=O stretching	1740-1720	strong
	C-H bending	1390-1380	medium
aliphatic ether	C-O stretching	1150-1085	strong
aliphatic ketone	C=O stretching	1725-1705	strong	or cyclohexanone or cyclopentenone
aliphatic primary amine	N-H stretching	3400-3300	medium
alkane	C-H stretching	3000-2840	medium
	C-H bending	1465	medium	methylene group
	C-H bending	1450	medium	methyl group
	C-H bending	1385-1380	medium	gem dimethyl
	C-H stretching	3100-3000	medium
	C=C stretching	1678-1668	weak	disubstituted (trans)
	C=C stretching	1675-1665	weak	trisubstituted
	C=C stretching	1675-1665	weak	tetrasubstituted
	C=C stretching	1662-1626	medium	disubstituted (cis)
	C=C stretching	1658-1648	medium	vinylidene
	C=C stretching	1648-1638	strong	monosubstituted
	C=C bending	995-985	strong	monosubstituted
	C=C bending	980-960	strong	disubstituted (trans)
	C=C bending	895-885	strong	vinylidene
	C=C bending	840-790	medium	trisubstituted
	C=C bending	730-665	strong	disubstituted (cis)
alkyl aryl ether	C-O stretching	1275-1200	strong
alkyne	C-H stretching	3333-3267	strong, sharp
	CΞC stretching	2260-2190	weak	disubstituted
	CΞC stretching	2140-2100	weak	monosubstituted
allene	C=C=C stretching	2000-1900	medium
amine	N-H bending	1650-1580	medium
	C-N stretching	1250-1020	medium
amine salt	N-H stretching	3000-2800	strong, broad
anhydride	C=O stretching	1818	strong
	CO-O-CO stretching	1050-1040	strong, broad
aromatic amine	C-N stretching	1342-1266	strong
aromatic compound	C-H bending	2000-1650	weak	overtone
aromatic ester	C-O stretching	1310-1250	strong
azide	N=N=N stretching	2160-2120	strong
benzene derivative		700 ± 20
carbodiimide	N=C=N stretching	2145-2120	strong
carbon dioxide	O=C=O stretching	2349	strong
carboxylic acid	O-H stretching	3300-2500	strong, broad	usually centered on 3000 cm⁻¹
	C=O stretching	1760	strong	monomer
	C=O stretching	1720-1706	strong	dimer
	O-H bending	1440-1395	medium
conjugated acid	C=O stretching	1710-1680	strong	dimer
conjugated acid halide	C=O stretching	1800-1770	strong
conjugated aldehyde	C=O stretching	1710-1685	strong
conjugated alkene	C=C stretching	1650-1600	medium
conjugated anhydride	C=O stretching	1775	strong
conjugated ketone	C=O stretching	1685-1666	strong
cyclic alkene	C=C stretching	1650-1566	medium
cyclopentanone	C=O stretching	1745	strong
ester	C-O stretching	1210-1163	strong
esters	C=O stretching	1750-1735	strong	6-membered lactone
fluoro compound	C-F stretching	1400-1000	strong
halo compound	C-Cl stretching	850-550	strong
	C-Br stretching	690-515	strong
	C-I stretching	600-500	strong
imine / oxime	C=N stretching	1690-1640	medium
isocyanate	N=C=O stretching	2275-2250	strong, broad
isothiocyanate	N=C=S stretching	2140-1990	strong
ketene	C=C=O stretching	2150
ketenimine	C=C=N stretching	2000
monosubstituted	C-H bending	750 ± 20	strong
nitrile	CΞN stretching	2260-2222	weak
nitro compound	N-O stretching	1550-1500	strong
none		3330-3250
none		1870-1540
none		1750
none		1720
none		1372-1290
none		1375
none		1370-1365
none		1200-1185
none		1204-1177
none		1195-1168
none		1170-1155
none		1165-1150		hydrate: 1230-1120
none		1160-1120
none		1075-1020
none		1075-1020
none		915-905
none		810 ± 20
none		780 ± 20
none		(700 ± 20)
none		(700 ± 20)
phenol	O-H bending	1390-1310	medium
primary alcohol	C-O stretching	1085-1050	strong
primary amide	C=O stretching	1690	strong	free (associated: 1650)
	N-H stretching	3500	medium
secondary alcohol	C-O stretching	1124-1087	strong
secondary amide	C=O stretching	1680	strong	free (associated: 1640)
secondary amine	N-H stretching	3350-3310	medium
sulfate	S=O stretching	1415-1380	strong
sulfonamide	S=O stretching	1370-1335	strong
sulfonate	S=O stretching	1372-1335	strong
sulfone	S=O stretching	1350-1300	strong
sulfonic acid	S=O stretching	1350-1342	strong	anhydrous
sulfonyl chloride	S=O stretching	1410-1380	strong
sulfoxide	S=O stretching	1070-1030	strong
tertiary alcohol	C-O stretching	1205-1124	strong
tertiary amide	C=O stretching	1680	strong	free (associated: 1630)
thiocyanate	S-CΞN stretching	2175-2140	strong
thiol	S-H stretching	2600-2550	weak
vinyl / phenyl ester	C=O stretching	1770-1780	strong
vinyl ether	C-O stretching	1225-1200	strong
α,β-unsaturated ester	C=O stretching	1730-1715	strong	or formates
α,β-unsaturated ketone	C=C stretching	1620-1610	strong
δ-lactam	C=O stretching	1650	strong	γ: 1750-1700 β: 1760-1730
δ-lactone	C=O stretching	1750-1735	strong	γ: 1770
1,2,3,4-tetrasubstituted
1,2,3-trisubstituted	C-H bending	780 ± 20	strong
	C-H bending	880 ± 20	strong
1,2-disubstituted	C-H bending	755 ± 20	strong
	C-H bending	880 ± 20	strong
1,4-disubstituted or	C-H bending	810 ± 20	strong

To use an IR spectrum table, first need to find the frequency or compound in the first column, depending on which type of chart that is being used. Then find the corresponding values for absorption, appearance and other attributes. The value for absorption is usually in cm⁻¹.

NOTE: NOT ALL FREQUENCIES HAVE A RELATED COMPOUND.

Applications[]

Evaluation of Dual - Spectrum IR Spectrogram System on Invasive Ductal Carcinoma (IDC) Breast cancer[]

Breast Cancer Gross Appearance

Invasive Ductal Carcinoma (IDC) is one of the common types of breast cancer which accounts for 8 out of 10 of all invasive breast cancers. According to the American Cancer Society, more than 180,000 women in the United States find out that they have breast cancers each year, and most are diagnosed with this specific type of cancer.^[6] While it is essential to detect breast cancer early to reduce the death rate there may be already more than 10,000,000 cells in breast cancer when it can be observed by x-ray mammograms. however, the IR Spectrum proposed by Szu et al seems to be more promising in detecting breast cancer cells several months ahead of a mammogram. Clinical tests have been carried out with approval of Institutional Review Board of National Taiwan University Hospital. So from August 2007 to June 2008 35 patients aged between (30-66) with an average age of 49 were enlisted in this project. the results established that about 63% of the success rate could be achieved with the cross-sectional data. Therefore the results concluded that breast cancers may be detected more accurately by cross-referencing S₁ maps of multiple three-points.^[7]

Molecular spectroscopic Methods to Elucidation of Lignin Structure[]

A Ligninin plant cell is a complex amorphous polymer and it is biosynthesized from three aromatic alcohols, namely P-Coumaryl, Coniferyl, and Sinapyl alcohols. Lignin is a highly branched polymer and accounts for 15-30% by weight of lignocellulosic biomass (LCBM), so the structure of lignin will vary significantly according to the type of LCBM and the composition will depend on the degradation process.^[8] This biosynthesis process is mainly consists of radical coupling reactions and it generates a particular lignin polymer in each plant species. So due to having a complex structure, various molecular spectroscopic methods have been applied to resolve the aromatic units and different interunit linkages in lignin from distinct plant species.^[9]

General Lignin Structure

References[]

^ "Spectrochemical Analysis". Britannica. 23 September 2019. Retrieved 1 May 2021.
^ Deglr6328 (10 September 2006). "Dichloromethane near IR Spectrum". Wikipedia Commons. Retrieved 29 April 2021.
^ "The Era of Classical Spectroscopy". MIT Spectroscopy Lab - History. Retrieved 1 May 2021.
^ "IR spectrum table & chart". Millipore Sigma. Retrieved 29 April 2021.
^ "IR spectrum table & chart". Millipore Sigma. Retrieved 29 April 2021.
^ "Invasive Ductal Carcinoma: Diagnosis, Treatment, and More". Breastcancer.org. 21 January 2020. Retrieved 2 May 2020.
^ Lee, Chuang, Hsieh, Lee, Lee, Shih, Lee, Huang, Chang, Chen, Chia-Yen, Ching-Cheng, Hsin-Yu, Wan-Rou, Ching-Yen, Shyang-Rong, Si-Chen, Chiun-Sheng, Yeun-Chung, Chung-Ming Chen (14 June 2011). EVALUATION OF DUAL-SPECTRUM IR SPECTROGRAM SYSTEM ON INVASIVE DUCTAL CARCINOMA (IDC) BREAST CANCER. Institute of Biomedical Engineering, National Taiwan University, Taiwan. pp. 427–433.CS1 maint: multiple names: authors list (link)
^ Lu, Lu, Hu, Xie, Wei, Fan, Yao, Yong-Chao, Hong-Qin, Feng-Jin, Xian-Yong, Xing (29 November 2017). "Structural Characterization of Lignin and Its Degradation Products with Spectroscopic Methods". Journal of Spectroscopy. Retrieved 2 May 2020.CS1 maint: multiple names: authors list (link)
^ You, Xu, Tingting, Feng (5 October 2016). "Applications of Molecular Spectroscopic Methods to the Elucidation of Lignin Structure". IntechOpen. Retrieved 1 May 2021.

[1] "Spectrochemical Analysis". Britannica. 23 September 2019. Retrieved 1 May 2021.

[2] Deglr6328 (10 September 2006). "Dichloromethane near IR Spectrum". Wikipedia Commons. Retrieved 29 April 2021.

[3] "The Era of Classical Spectroscopy". MIT Spectroscopy Lab - History. Retrieved 1 May 2021.

[4] "IR spectrum table & chart". Millipore Sigma. Retrieved 29 April 2021.

[5] "IR spectrum table & chart". Millipore Sigma. Retrieved 29 April 2021.

[6] "Invasive Ductal Carcinoma: Diagnosis, Treatment, and More". Breastcancer.org. 21 January 2020. Retrieved 2 May 2020.

[7] Lee, Chuang, Hsieh, Lee, Lee, Shih, Lee, Huang, Chang, Chen, Chia-Yen, Ching-Cheng, Hsin-Yu, Wan-Rou, Ching-Yen, Shyang-Rong, Si-Chen, Chiun-Sheng, Yeun-Chung, Chung-Ming Chen (14 June 2011). EVALUATION OF DUAL-SPECTRUM IR SPECTROGRAM SYSTEM ON INVASIVE DUCTAL CARCINOMA (IDC) BREAST CANCER. Institute of Biomedical Engineering, National Taiwan University, Taiwan. pp. 427–433.CS1 maint: multiple names: authors list (link)

[8] Lu, Lu, Hu, Xie, Wei, Fan, Yao, Yong-Chao, Hong-Qin, Feng-Jin, Xian-Yong, Xing (29 November 2017). "Structural Characterization of Lignin and Its Degradation Products with Spectroscopic Methods". Journal of Spectroscopy. Retrieved 2 May 2020.CS1 maint: multiple names: authors list (link)

[9] You, Xu, Tingting, Feng (5 October 2016). "Applications of Molecular Spectroscopic Methods to the Elucidation of Lignin Structure". IntechOpen. Retrieved 1 May 2021.

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