Spectroscopy and dynamics of double proton transfer in formic acid dimer

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Standard

Spectroscopy and dynamics of double proton transfer in formic acid dimer. / Mackeprang, Kasper; Xu, Zhen-Hao; Maroun, Zeina; Meuwly, Markus; Kjærgaard, Henrik Grum.

I: Physical Chemistry Chemical Physics, Bind 18, Nr. 35, 2016, s. 24654-24662.

Publikation: Bidrag til tidsskriftTidsskriftartikelForskningfagfællebedømt

Harvard

Mackeprang, K, Xu, Z-H, Maroun, Z, Meuwly, M & Kjærgaard, HG 2016, 'Spectroscopy and dynamics of double proton transfer in formic acid dimer', Physical Chemistry Chemical Physics, bind 18, nr. 35, s. 24654-24662. https://doi.org/10.1039/c6cp03462d

APA

Mackeprang, K., Xu, Z-H., Maroun, Z., Meuwly, M., & Kjærgaard, H. G. (2016). Spectroscopy and dynamics of double proton transfer in formic acid dimer. Physical Chemistry Chemical Physics, 18(35), 24654-24662. https://doi.org/10.1039/c6cp03462d

Vancouver

Mackeprang K, Xu Z-H, Maroun Z, Meuwly M, Kjærgaard HG. Spectroscopy and dynamics of double proton transfer in formic acid dimer. Physical Chemistry Chemical Physics. 2016;18(35):24654-24662. https://doi.org/10.1039/c6cp03462d

Author

Mackeprang, Kasper ; Xu, Zhen-Hao ; Maroun, Zeina ; Meuwly, Markus ; Kjærgaard, Henrik Grum. / Spectroscopy and dynamics of double proton transfer in formic acid dimer. I: Physical Chemistry Chemical Physics. 2016 ; Bind 18, Nr. 35. s. 24654-24662.

Bibtex

@article{aff3c7796996462781e05dfb1c23988b,
title = "Spectroscopy and dynamics of double proton transfer in formic acid dimer",
abstract = "We present the isolated gas phase infrared spectra of formic acid dimer, (HCOOH)2, and its deuterated counterpart formic-d acid, (DCOOH)2, at room temperature. The formic acid dimer spectrum was obtained by spectral subtraction of a spectrum of formic acid vapor recorded at low pressure from that recorded at a higher pressure. The spectra of formic acid vapor contain features from both formic acid monomer and formic acid dimer, but at low and high pressures of formic acid, the equilibrium is pushed towards the monomer and dimer, respectively. A similar approach was used for the formic-d acid dimer. Building on the previous development of the Molecular Mechanics with Proton Transfer (MMPT) force field for simulating proton transfer reactions, molecular dynamics (MD) simulations were carried out to interpret the experimental spectra in the OH-stretching region. Within the framework of MMPT, a combination of symmetric single and double minimum potential energy surfaces (PESs) provides a good description of the double proton transfer PES. In a next step, potential morphing together with electronic structure calculations at the B3LYP and MP2 level of theory was used to align the computed and experimentally observed spectral features in the OH-stretching region. From this analysis, a barrier for double proton transfer between 5 and 7 kcal mol-1 was derived, which compares with a CCSD(T)/aug-cc-pVTZ calculated barrier of 7.9 kcal mol-1. Such a combination of experimental and computational techniques for estimating barriers for proton transfer in gas phase systems is generic and holds promise for further improved PESs and energetics of these important systems. Additional MD simulations at the semi-empirical DFTB level of theory agree quite well for the center band position but underestimate the width of the OH-stretching band.",
author = "Kasper Mackeprang and Zhen-Hao Xu and Zeina Maroun and Markus Meuwly and Kj{\ae}rgaard, {Henrik Grum}",
year = "2016",
doi = "10.1039/c6cp03462d",
language = "English",
volume = "18",
pages = "24654--24662",
journal = "Physical Chemistry Chemical Physics",
issn = "1463-9076",
publisher = "Royal Society of Chemistry",
number = "35",

}

RIS

TY - JOUR

T1 - Spectroscopy and dynamics of double proton transfer in formic acid dimer

AU - Mackeprang, Kasper

AU - Xu, Zhen-Hao

AU - Maroun, Zeina

AU - Meuwly, Markus

AU - Kjærgaard, Henrik Grum

PY - 2016

Y1 - 2016

N2 - We present the isolated gas phase infrared spectra of formic acid dimer, (HCOOH)2, and its deuterated counterpart formic-d acid, (DCOOH)2, at room temperature. The formic acid dimer spectrum was obtained by spectral subtraction of a spectrum of formic acid vapor recorded at low pressure from that recorded at a higher pressure. The spectra of formic acid vapor contain features from both formic acid monomer and formic acid dimer, but at low and high pressures of formic acid, the equilibrium is pushed towards the monomer and dimer, respectively. A similar approach was used for the formic-d acid dimer. Building on the previous development of the Molecular Mechanics with Proton Transfer (MMPT) force field for simulating proton transfer reactions, molecular dynamics (MD) simulations were carried out to interpret the experimental spectra in the OH-stretching region. Within the framework of MMPT, a combination of symmetric single and double minimum potential energy surfaces (PESs) provides a good description of the double proton transfer PES. In a next step, potential morphing together with electronic structure calculations at the B3LYP and MP2 level of theory was used to align the computed and experimentally observed spectral features in the OH-stretching region. From this analysis, a barrier for double proton transfer between 5 and 7 kcal mol-1 was derived, which compares with a CCSD(T)/aug-cc-pVTZ calculated barrier of 7.9 kcal mol-1. Such a combination of experimental and computational techniques for estimating barriers for proton transfer in gas phase systems is generic and holds promise for further improved PESs and energetics of these important systems. Additional MD simulations at the semi-empirical DFTB level of theory agree quite well for the center band position but underestimate the width of the OH-stretching band.

AB - We present the isolated gas phase infrared spectra of formic acid dimer, (HCOOH)2, and its deuterated counterpart formic-d acid, (DCOOH)2, at room temperature. The formic acid dimer spectrum was obtained by spectral subtraction of a spectrum of formic acid vapor recorded at low pressure from that recorded at a higher pressure. The spectra of formic acid vapor contain features from both formic acid monomer and formic acid dimer, but at low and high pressures of formic acid, the equilibrium is pushed towards the monomer and dimer, respectively. A similar approach was used for the formic-d acid dimer. Building on the previous development of the Molecular Mechanics with Proton Transfer (MMPT) force field for simulating proton transfer reactions, molecular dynamics (MD) simulations were carried out to interpret the experimental spectra in the OH-stretching region. Within the framework of MMPT, a combination of symmetric single and double minimum potential energy surfaces (PESs) provides a good description of the double proton transfer PES. In a next step, potential morphing together with electronic structure calculations at the B3LYP and MP2 level of theory was used to align the computed and experimentally observed spectral features in the OH-stretching region. From this analysis, a barrier for double proton transfer between 5 and 7 kcal mol-1 was derived, which compares with a CCSD(T)/aug-cc-pVTZ calculated barrier of 7.9 kcal mol-1. Such a combination of experimental and computational techniques for estimating barriers for proton transfer in gas phase systems is generic and holds promise for further improved PESs and energetics of these important systems. Additional MD simulations at the semi-empirical DFTB level of theory agree quite well for the center band position but underestimate the width of the OH-stretching band.

U2 - 10.1039/c6cp03462d

DO - 10.1039/c6cp03462d

M3 - Journal article

C2 - 27545453

AN - SCOPUS:84984991438

VL - 18

SP - 24654

EP - 24662

JO - Physical Chemistry Chemical Physics

JF - Physical Chemistry Chemical Physics

SN - 1463-9076

IS - 35

ER -

ID: 169730112