Cite this article as:

Berezin K. V., Nechaev V. V., Kozlov O. ., Novoselova A. V., Chernavina M. L., Berezin V. I., Berezina M. ., Novoselov V. V. The Manifestation’s Research of the Pair Association in the Pyridine’s Ir-Spectrums by the Matrix Isolation Technique. Izvestiya of Saratov University. New series. Series Physics, 2015, vol. 15, iss. 1, pp. 14-20. DOI: https://doi.org/10.18500/1817-3020-2015-15-1-14-20

Heading: 
Physics
UDC: 
539.182/.184, 519.677
Language: 
Russian

The Manifestation’s Research of the Pair Association in the Pyridine’s Ir-Spectrums by the Matrix Isolation Technique

Authors: 
Berezin Kirill Valentinovich, Saratov State University, 410012, Russia, Saratov, Astrakhanskaya street, 83, berezinkv@yandex.ru
Nechaev Vladimir Vladimirovich, Yuri Gagarin State Technical University of Saratov, 77, Politechnicheskaya Str., Saratov, 410054, Russia, vl-nechaev@ya.ru
Kozlov Oleg V., Saratov State University, 410012, Russia, Saratov, Astrakhanskaya street, 83, kozlovov85@mail.ru
Novoselova Anna Vladimirovna, Saratov State University, 410012, Russia, Saratov, Astrakhanskaya street, 83, nusena1975@mail.ru
Chernavina Mariya Leonidovna, Saratov State University, 410012, Russia, Saratov, Astrakhanskaya street, 83, snake-naja@mail.ru
Berezin Valentine Ivanovich, Saratov State University, 410012, Russia, Saratov, Astrakhanskaya street, 83, berezin@sgu.ru
Berezina Maxim Kirillovich, Saratov State University, 410012, Russia, Saratov, Astrakhanskaya street, 83, berezin@sgu.ru
Novoselov Vladimir Vladimirovich, Saratov State University, 410012, Russia, Saratov, Astrakhanskaya street, 83, nusena1975@mail.ru
Abstract

The calculation of structure, frequencies of normal fluctuations and the strips intensity in IR-spectrums of five dimer of pyridine with hydrogen communication  has been performed by the matrix solation technique B3LYP/6-311+G (d, p). The number’s modeling of the difficult oscillatory contours in the pyridine’s IR-spectrum was executed taking into account the intermolecular interaction. It is shown that the hydrogen communications of the pair self-associatesthe brought the big contribution to formation of strips of the satellites complicating structure of oscillatory strips of monomeric pyridine  in the matrix-isolated low-temperature IR-spectrum. The detailed interpretation of the low-temperature matrix isolated IR-spectrum of H5  D5 pyridine absorption is offered. Thermodynamic characteris-tics of complexes formation taking into account a basic peak-a-boo mistake are calculated.

Key words: 
Infrared (oscillatory) spectroscopy, IR-spectrum, matrix isolation technique
DOI: 
https://doi.org/10.18500/1817-3020-2015-15-1-14-20
References

1. Klaboe P., Nielsen C. J. Recent advances in infrared matrix isolation spectroscopy // Analyst (Cambridge, United Kingdom). 1992. Vol. 117, № 3. P. 335–341.

2. Пиментел Дж. Колебательная спектроскопия / под ред. A. Барнса и У. Орвилл-Томаса. М. : Мир, 1981. 480 с.

3. Барри Ф. М., Тохадзе К. Г. Водородная связь / под ред. Н. Д. Соколова. М. : Наука, 1981. 286 с.

4. Bürger H., Schneider W., Sommer S., Thiel W., Will-ner H. Generation of gold ions in the solid state or in f uorosulfuric acid solution and their identif cation by ESR // J. Chem. Phys. 1991. Vol. 95, № 8. P. 5660-9.

5. Shepherd R. A., Graham W. R. M. Formation and Identif cation of Interstellar Molecule Linear C5H from Photolysis of Methane Dispersed in Solid Neon // J. Chem. Phys. 1987. Vol. 86. P. 2600–2605.

6. Goodman M. A., Sweany R. L., Flurry R. L. Jr. Iinfrared spectra of matrix-isolated, crystalline solid, and gas phase C3-C6 n-alkanes // J. Phys. Chem. 1983. Vol. 87, № 10. P. 1753–1757.

7. Engdahl A., Nelander B. Infrared spectrum of cis-glyoxal // Chem. Phys. Lett. 1988. Vol. 148, № 2–3. P. 264–275.

8. Шапетько Н. Н., Базов В. П. Проявление туннельных эффектов в инфракрасных спектрах ацетилацетона в матричной изоляции при 14 К // Журн. физ. химии. 1989. Т. 63, № 10. С. 2832–2835.

9. Destexhe A., Smets J., Adamowicz L., Maes G. Matrix-Isolation FT-IR Studies and AbInitio Calculations of Hydrogen-Bonded. Complexes of Molecules Modeling Cytosine // J. Phys. Chem. 1994. Vol. 98, № 5. P. 1506–1514.

10. Szczesniak M., Nowak M. J., Szczepaniak K., Chin S., Scott I., Person W. B. Matrix isolation studies of nucleic acid constituents-III. 1-Methyluracil, 3-methyluracil and 1,3-dimethyluracil monomers // Spectrochim. Acta. A. 1985. Vol. 41, № 1–2. P. 233–236.

11. Степаньян С. Г., Шеина Г. Г., Радченко Е. Д., Благой Ю. П. Инфракрасные спектры и таутомерия изоцитозина в аргоновой матрице // Журн. физ. хи-мии. 1989. Т. 63, № 11. С. 3008–3014.

12.  Nowak M. J., Lapinski L., Kwiatkowski J. S., Leszczyń-ski J. Molecular Structure and Infrared Spectra of Ad-enine. Experimental Matrix Isolation and Density Func-tional Theory Study of Adenine (15)N Isotopomers // J . Phys. Chem. 1996. Vol. 100, № 9. P. 3527–3534.

13.  Stepanian S. G., Reva I. D., Radchenko E. D., Ada-mowicz L. Conformational Behavior of Alanine. Mat-rix-Isolation Infrared and Theoretical DFT and ab Initio Study // J. Phys. Chem. A. 1998. Vol. 102, № 24. P. 4623–4629.

14. Ivanov A. Yu., Sheina G., Blagoi Yu. P. FTIR spec-troscopic study of the UV-induced rotamerization of glycine in the low temperature matrices (Kr, Ar, Ne) // Spectrochim. Acta. A. 1999. Vol. 55, № 1. P. 219–228.

15. Kincaid J. R., Urban M. W., Watanabe T., Nakamoto K. Infrared Spectra of Matrix-Isolated Metal Complexes of Octaethylporphine // J. Phys. Chem. 1983. Vol. 87, № 16. P. 3096–3101.

16. Radziszewski J. G., Nepraš M., Balaji V., Waluk J., Vogel E., Michl J. Polarized Infrared Spectra of Photoori-ented Matrix-Isolated Free-Base Porphyn Isotopomers // J. Phys. Chem. 1995. Vol. 99. P. 14254–14260.

17. Молекулярные взаимодействия / под ред. Г. Ратай-чика, У. Орвилла-Томаса : в 2 т. М. : Мир, 1984. Т. 2. 600 с.

18. Fujimoto N., Toyama A., Takeuchi H. Effect of hydrogen bonding on the UV resonance Raman bands of the ad-enine ring and its C8-deuterated analog // J. Mol. Struct. 1998. Vol. 447, № 1–2. P. 61–69.

19. Efremov R. G., Feofanov A. N., Dzhandzhugazyan K. N., Modyanov N. N., Nabiev I. R. Study of ATP binding in the active site of Na+, K+ ATpase as probed by ultraviolet resonance Raman Spectroscopy // FEBS Lett. 1990. Vol. 260, № 2. P. 257–260.

20. Taddei G., Castellucci E., Verderame F. D. Pair Associa-tion in Matrix Isolated Pyridine // J. Chem. Phys. 1970. Vol. 53, № 6. P. 2407–2411.

21. Moller C., Plesset M. S. Note on an approximation treat-ment for many – electron system // Phys. Rev. 1934. Vol. 46, № 7. P. 618–622.

22. Кон В. Электронная структура вещества – волновые функции и функционалы плотности // УФН. 2002. Т. 172, № 3. C. 336–348.

23. Krishnan R., Schlegel H. B., Pople J. A. Self-consis-tent orbital methods. XX. A basis set for correlated wave functions // J.Chem. Phys. 1980. Vol. 72, № 1. P. 650–654.

24. Pople J. A., Head-Gordon M., Raghavachari K. Quadratic conf guration interaction. A general technique for deter-mining electron correlation energies // J. Chem. Ph ys. 1987. Vol. 87, № 10.  P. 5968–5975.

25. Becke A. D. Density-functional thermochemistry. III. The role of exact exchange // J. Chem. Phys. 1993. Vol. 98, № 7. P. 5648–5652.

26. Lee C., Yang W., Parr R. G. Development of the Colle-Solvetti correlation-energy formula into a functional of the electron density // Phys. Rev. 1988. Vol. 37B, № 2. P. 785–789.

27.  Frisch M. J., Trucks G. W., Schlegel H . B. et al. Gaussian 98 / Gaussian Inc. Pittsburgh, PA, 1998.

28. Yoshida H., Ehara A., Matsuura H. Density functional vibrational analysis using wavenumber-linear scale factors // Chem. Phys. Lett. 2000. V ol. 325, № 4. P. 477–483.

29. Portmann S., Fluekiger P.F. URL: http://www.cscs.ch/molekel/

30. Березин К. В., Березин В. И., Кирносов Н. А., Бере-зин М. К. Учет межмолекулярного взаимодействия в рамках современных квантовомеханических методов расчета структуры и колебательных спектров многоатомных молекул // Проблемы оптической физики и биофотоники : материалы 12-й Междунар. Молодежной науч . школы по оптике, лазерной физике и биофотонике. Саратов : Новый ветер, 2009. С. 181–188

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