The effect of large amplitude motions on the vibrational intensities in hydrogen bonded complexes

Kasper Mackeprang; Vesa Hänninen; Lauri Halonen; Henrik Grum Kjærgaard

doi:10.1063/1.4913737

The effect of large amplitude motions on the vibrational intensities in hydrogen bonded complexes

Kasper Mackeprang, Vesa Hänninen, Lauri Halonen, Henrik Grum Kjærgaard

Department of Chemistry

29 Citations (Scopus)

Abstract

We have developed a model to calculate accurately the intensity of the hydrogen bonded XH-stretching vibrational transition in hydrogen bonded complexes. In the Local Mode Perturbation Theory (LMPT) model, the unperturbed system is described by a local mode (LM) model, which is perturbed by the intermolecular modes of the hydrogen bonded system that couple with the intramolecular vibrations of the donor unit through the potential energy surface. We have applied the model to three complexes containing water as the donor unit and different acceptor units, providing a series of increasing complex binding energy: H2O⋯N2, H2O⋯H2O, and H2O⋯NH3. Results obtained by the LMPT model are presented and compared with calculated results obtained by other vibrational models and with previous results from gas-phase and helium-droplet experiments. We find that the LMPT model reduces the oscillator strengths of the fundamental hydrogen bonded OH-stretching transition relative to the simpler LM model.

Original language	English
Article number	094304
Journal	Journal of Chemical Physics
Volume	142
Number of pages	10
ISSN	0021-9606
DOIs	https://doi.org/10.1063/1.4913737
Publication status	Published - 7 Mar 2015

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title = "The effect of large amplitude motions on the vibrational intensities in hydrogen bonded complexes",

abstract = "We have developed a model to calculate accurately the intensity of the hydrogen bonded XH-stretching vibrational transition in hydrogen bonded complexes. In the Local Mode Perturbation Theory (LMPT) model, the unperturbed system is described by a local mode (LM) model, which is perturbed by the intermolecular modes of the hydrogen bonded system that couple with the intramolecular vibrations of the donor unit through the potential energy surface. We have applied the model to three complexes containing water as the donor unit and different acceptor units, providing a series of increasing complex binding energy: H2O⋯N2, H2O⋯H2O, and H2O⋯NH3. Results obtained by the LMPT model are presented and compared with calculated results obtained by other vibrational models and with previous results from gas-phase and helium-droplet experiments. We find that the LMPT model reduces the oscillator strengths of the fundamental hydrogen bonded OH-stretching transition relative to the simpler LM model.",

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T1 - The effect of large amplitude motions on the vibrational intensities in hydrogen bonded complexes

AU - Mackeprang, Kasper

AU - Hänninen, Vesa

AU - Halonen, Lauri

AU - Kjærgaard, Henrik Grum

PY - 2015/3/7

Y1 - 2015/3/7

N2 - We have developed a model to calculate accurately the intensity of the hydrogen bonded XH-stretching vibrational transition in hydrogen bonded complexes. In the Local Mode Perturbation Theory (LMPT) model, the unperturbed system is described by a local mode (LM) model, which is perturbed by the intermolecular modes of the hydrogen bonded system that couple with the intramolecular vibrations of the donor unit through the potential energy surface. We have applied the model to three complexes containing water as the donor unit and different acceptor units, providing a series of increasing complex binding energy: H2O⋯N2, H2O⋯H2O, and H2O⋯NH3. Results obtained by the LMPT model are presented and compared with calculated results obtained by other vibrational models and with previous results from gas-phase and helium-droplet experiments. We find that the LMPT model reduces the oscillator strengths of the fundamental hydrogen bonded OH-stretching transition relative to the simpler LM model.

AB - We have developed a model to calculate accurately the intensity of the hydrogen bonded XH-stretching vibrational transition in hydrogen bonded complexes. In the Local Mode Perturbation Theory (LMPT) model, the unperturbed system is described by a local mode (LM) model, which is perturbed by the intermolecular modes of the hydrogen bonded system that couple with the intramolecular vibrations of the donor unit through the potential energy surface. We have applied the model to three complexes containing water as the donor unit and different acceptor units, providing a series of increasing complex binding energy: H2O⋯N2, H2O⋯H2O, and H2O⋯NH3. Results obtained by the LMPT model are presented and compared with calculated results obtained by other vibrational models and with previous results from gas-phase and helium-droplet experiments. We find that the LMPT model reduces the oscillator strengths of the fundamental hydrogen bonded OH-stretching transition relative to the simpler LM model.

U2 - 10.1063/1.4913737

DO - 10.1063/1.4913737

M3 - Journal article

C2 - 25747078

SN - 0021-9606

VL - 142

JO - The Journal of Chemical Physics

JF - The Journal of Chemical Physics

M1 - 094304

ER -

The effect of large amplitude motions on the vibrational intensities in hydrogen bonded complexes

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