Identification of vibrational modes in thymine bases by broadband far-infrared absorption spectroscopy

Yutaka Abe; Tomofumi Seki; Yoshimichi Ohki; Maya Mizuno

doi:10.7567/1347-4065/ab066e

Identification of vibrational modes in thymine bases by broadband far-infrared absorption spectroscopy

Yutaka Abe, Tomofumi Seki, Yoshimichi Ohki, Maya Mizuno

Kagami Memorial Research Institute for Materials Science and Technology

Research output: Contribution to journal › Article › peer-review

7 Citations (Scopus)

Abstract

Far-infrared and THz absorption spectra were obtained for thymine bases. Quantum chemical calculations were also conducted to simulate the far-infrared spectrum using density functional theory. Three models were used for the simulations. In one model, a thymine monomer was assumed. The second model assumed a thymine dimer, where two pyrimidine rings were aligned antiparallel. The last model assumed a thymine trimer, in which four hydrogen bonds were formed in three pyrimidine rings placed on the same plane. By comparing the measurements and simulations, almost all the absorption peaks appearing from 100 to 600 cm^-1 could be assigned to torsional or skeletal vibrations of a pyrimidine ring. On the other hand, absorption peaks appearing in the THz range from 16.7 to 167 cm^-1 were assigned to intermolecular vibrations.

Original language	English
Article number	052002
Journal	Japanese journal of applied physics
Volume	58
Issue number	5
DOIs	https://doi.org/10.7567/1347-4065/ab066e
Publication status	Published - 2019

ASJC Scopus subject areas

Engineering(all)
Physics and Astronomy(all)

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title = "Identification of vibrational modes in thymine bases by broadband far-infrared absorption spectroscopy",

abstract = "Far-infrared and THz absorption spectra were obtained for thymine bases. Quantum chemical calculations were also conducted to simulate the far-infrared spectrum using density functional theory. Three models were used for the simulations. In one model, a thymine monomer was assumed. The second model assumed a thymine dimer, where two pyrimidine rings were aligned antiparallel. The last model assumed a thymine trimer, in which four hydrogen bonds were formed in three pyrimidine rings placed on the same plane. By comparing the measurements and simulations, almost all the absorption peaks appearing from 100 to 600 cm-1 could be assigned to torsional or skeletal vibrations of a pyrimidine ring. On the other hand, absorption peaks appearing in the THz range from 16.7 to 167 cm-1 were assigned to intermolecular vibrations.",

author = "Yutaka Abe and Tomofumi Seki and Yoshimichi Ohki and Maya Mizuno",

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T1 - Identification of vibrational modes in thymine bases by broadband far-infrared absorption spectroscopy

AU - Abe, Yutaka

AU - Seki, Tomofumi

AU - Ohki, Yoshimichi

AU - Mizuno, Maya

PY - 2019

Y1 - 2019

N2 - Far-infrared and THz absorption spectra were obtained for thymine bases. Quantum chemical calculations were also conducted to simulate the far-infrared spectrum using density functional theory. Three models were used for the simulations. In one model, a thymine monomer was assumed. The second model assumed a thymine dimer, where two pyrimidine rings were aligned antiparallel. The last model assumed a thymine trimer, in which four hydrogen bonds were formed in three pyrimidine rings placed on the same plane. By comparing the measurements and simulations, almost all the absorption peaks appearing from 100 to 600 cm-1 could be assigned to torsional or skeletal vibrations of a pyrimidine ring. On the other hand, absorption peaks appearing in the THz range from 16.7 to 167 cm-1 were assigned to intermolecular vibrations.

AB - Far-infrared and THz absorption spectra were obtained for thymine bases. Quantum chemical calculations were also conducted to simulate the far-infrared spectrum using density functional theory. Three models were used for the simulations. In one model, a thymine monomer was assumed. The second model assumed a thymine dimer, where two pyrimidine rings were aligned antiparallel. The last model assumed a thymine trimer, in which four hydrogen bonds were formed in three pyrimidine rings placed on the same plane. By comparing the measurements and simulations, almost all the absorption peaks appearing from 100 to 600 cm-1 could be assigned to torsional or skeletal vibrations of a pyrimidine ring. On the other hand, absorption peaks appearing in the THz range from 16.7 to 167 cm-1 were assigned to intermolecular vibrations.

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Identification of vibrational modes in thymine bases by broadband far-infrared absorption spectroscopy

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