Infrared studies of CO2 doped Xe solutions in gas, liquid and solid phases. The fundamental nu(3) band and the Coriolis perturbed Fermi doublet (nu(1)+nu(1)(2),nu(1)+nu(11)(2))

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Infrared studies of CO2 doped Xe solutions in gas, liquid and solid phases. The fundamental nu(3) band and the Coriolis perturbed Fermi doublet (nu(1)+nu(1)(2),nu(1)+nu(11)(2)). / Rutkowski, KS; Melikova, SM ; Kolomiitsova, TD ; Filippov, NN; Koll, A.

In: Journal of Molecular Structure, Vol. 596, 26.09.2001, p. 179-183.

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

BibTeX

@article{17627ef672044bf689bffd5293affec4,

title = "Infrared studies of CO2 doped Xe solutions in gas, liquid and solid phases. The fundamental nu(3) band and the Coriolis perturbed Fermi doublet (nu(1)+nu(1)(2),nu(1)+nu(11)(2))",

abstract = "The IR absorption spectra of CO2 doped Xe solutions have been recorded in the range of the fundamental v(3)(Sigma (u)) band and of the Coriolis perturbed v(1) + v(2)(1), v(1) + v(2)(11) (pi (u)) Fermi doublet (v(1) + v(2) approximate to 3v(2)) in gas, liquid and solid phases. The characteristic transformation and rapid narrowing of the v(3) band, observed in the gas to liquid phase transition, shows marked hindering of the rotational motion of the CO2 molecule in dense Xe mixtures. It was found that the liquid to solid phase transition is accompanied by noticeable broadening of the v(3) band. The rotational motion of CO2 is not frozen in solid Xe at least near the freezing point. This is in contrast with sharp narrowing of the vibrational bands and so with blocking up rotations in the case of a heavier CS2 guest in the solid Xe host just below the freezing point. The intensity ratio A(v(1) + v(2)(1))/A(v(1) + v(2)(11)) of the Coriolis perturbed v(1) + v(2)(1), v(1) + v(2)(11) doublet reveals the noticeable increase from 8 +/- 1 in a low density gas to 18 +/- 2 in the liquid phase. The results obtained suggest remarkable modification of the second-order Coriolis coupling in the case of CO2 doped dense liquid Xe. (C) 2001 Elsevier Science B.V. All rights reserved.",

keywords = "vibrational spectra, CO2, noble gas solutions, phase transition, rotational relaxation processes, Coriolis coupling",

author = "KS Rutkowski and SM Melikova and TD Kolomiitsova and NN Filippov and A Koll",

year = "2001",

month = sep,

day = "26",

doi = "10.1016/S0022-2860(01)00711-6",

language = "Английский",

volume = "596",

pages = "179--183",

journal = "Journal of Molecular Structure",

issn = "0022-2860",

publisher = "Elsevier",

note = "null ; Conference date: 23-09-2000 Through 26-09-2000",

}

RIS

TY - JOUR

T1 - Infrared studies of CO2 doped Xe solutions in gas, liquid and solid phases. The fundamental nu(3) band and the Coriolis perturbed Fermi doublet (nu(1)+nu(1)(2),nu(1)+nu(11)(2))

AU - Rutkowski, KS

AU - Melikova, SM

AU - Kolomiitsova, TD

AU - Filippov, NN

AU - Koll, A

PY - 2001/9/26

Y1 - 2001/9/26

N2 - The IR absorption spectra of CO2 doped Xe solutions have been recorded in the range of the fundamental v(3)(Sigma (u)) band and of the Coriolis perturbed v(1) + v(2)(1), v(1) + v(2)(11) (pi (u)) Fermi doublet (v(1) + v(2) approximate to 3v(2)) in gas, liquid and solid phases. The characteristic transformation and rapid narrowing of the v(3) band, observed in the gas to liquid phase transition, shows marked hindering of the rotational motion of the CO2 molecule in dense Xe mixtures. It was found that the liquid to solid phase transition is accompanied by noticeable broadening of the v(3) band. The rotational motion of CO2 is not frozen in solid Xe at least near the freezing point. This is in contrast with sharp narrowing of the vibrational bands and so with blocking up rotations in the case of a heavier CS2 guest in the solid Xe host just below the freezing point. The intensity ratio A(v(1) + v(2)(1))/A(v(1) + v(2)(11)) of the Coriolis perturbed v(1) + v(2)(1), v(1) + v(2)(11) doublet reveals the noticeable increase from 8 +/- 1 in a low density gas to 18 +/- 2 in the liquid phase. The results obtained suggest remarkable modification of the second-order Coriolis coupling in the case of CO2 doped dense liquid Xe. (C) 2001 Elsevier Science B.V. All rights reserved.

AB - The IR absorption spectra of CO2 doped Xe solutions have been recorded in the range of the fundamental v(3)(Sigma (u)) band and of the Coriolis perturbed v(1) + v(2)(1), v(1) + v(2)(11) (pi (u)) Fermi doublet (v(1) + v(2) approximate to 3v(2)) in gas, liquid and solid phases. The characteristic transformation and rapid narrowing of the v(3) band, observed in the gas to liquid phase transition, shows marked hindering of the rotational motion of the CO2 molecule in dense Xe mixtures. It was found that the liquid to solid phase transition is accompanied by noticeable broadening of the v(3) band. The rotational motion of CO2 is not frozen in solid Xe at least near the freezing point. This is in contrast with sharp narrowing of the vibrational bands and so with blocking up rotations in the case of a heavier CS2 guest in the solid Xe host just below the freezing point. The intensity ratio A(v(1) + v(2)(1))/A(v(1) + v(2)(11)) of the Coriolis perturbed v(1) + v(2)(1), v(1) + v(2)(11) doublet reveals the noticeable increase from 8 +/- 1 in a low density gas to 18 +/- 2 in the liquid phase. The results obtained suggest remarkable modification of the second-order Coriolis coupling in the case of CO2 doped dense liquid Xe. (C) 2001 Elsevier Science B.V. All rights reserved.

KW - vibrational spectra

KW - CO2

KW - noble gas solutions

KW - phase transition

KW - rotational relaxation processes

KW - Coriolis coupling

U2 - 10.1016/S0022-2860(01)00711-6

DO - 10.1016/S0022-2860(01)00711-6

M3 - статья

VL - 596

SP - 179

EP - 183

JO - Journal of Molecular Structure

JF - Journal of Molecular Structure

SN - 0022-2860

Y2 - 23 September 2000 through 26 September 2000

ER -

ID: 41409705