Two-dimensional infrared spectroscopy and ultrafast anisotropy decay of water

Jansen, Thomas L. C.; Auer, Benjamin M.; Yang, Mino; Skinner, James

doi:10.1063/1.3454733

Cited by 107 publications

(170 citation statements)

References 45 publications

(90 reference statements)

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“…Despite the clear distinction between excitation and probing of lower and higher frequency modes in our experiments, we observe in-plane randomization of the transition dipole moment orientations on an ultrafast timescale. Excitation transfer alone, as for example between different water molecules with overlapping OH stretch spectra 51 , is not sufficient to account for this observation. For illustration consider the schematic picture of solvated nitrate ions in Fig.12.…”

Section: Discussionmentioning

confidence: 99%

Hydration Dynamics of Aqueous Nitrate

et al. 2013

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Aqueous nitrate, NO3-(aq), was studied by 2D-IR, UV-IR, and UV-UV time-resolved spectroscopies in combination with molecular dynamics (MD) simulations with the purpose of determining the hydration dynamics around the anion. In water, the D3h symmetry of NO3-is broken, and the degeneracy of the asymmetric-stretch modes is lifted. This provides a very sensitive probe of the ionwater interactions. The 2D-IR measurements reveal excitation exchange between the two nondegenerate asymmetric-stretch vibrations on a 300-fs time scale concomitant with fast anisotropy decay of the diagonal-peak signals. The MD simulations show that this is caused by jumps of the transition dipole orientations related to fluctuations of the hydrogen bonds connecting the nitrate ion to the nearest water molecules. Reorientation of the ion, which is associated with the hydrogen-bond breaking, was monitored by time-resolved UV-IR and UV-UV spectroscopy, revealing a 2-ps time constant. These time scales are very similar to those reported for isotope-labeled water, suggesting that NO3-(aq) has a labile hydration shell. connecting the nitrate ion to the nearest water molecules. Reorientation of the ion, which is associated with the hydrogen bond breaking, is monitored by time resolved UV-IR-and UV-UV spectroscopy, revealing a 2 ps time constant. These time scales are very similar to those reported for isotope-labeled water, suggesting that NO 3¯( aq) has a labile hydration shell.

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Section: Discussionmentioning

confidence: 99%

Hydration Dynamics of Aqueous Nitrate

et al. 2013

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“…Its vibrational relaxation dynamics following an initial OH-stretching excitation has been studied extensively by femtosecond (fs) time-resolved mid-infrared (MIR) spectroscopy. Immediately after laser-excitation of the v = 0 to v = 1 transition of the OH-stretching mode, the excess energy rapidly delocalizes onto neighboring water molecules thereby giving rise to an ultrafast loss of memory regarding the frequency of excitation as well as the orientation of the associated transition dipole [8][9][10]. These dynamics are facilitated by strong OH transition dipole interactions, i.e.…”

Section: Introductionmentioning

confidence: 99%

OH and NH Stretching Vibrational Relaxation of Liquid Ethanolamine

Knop

Lindner

Vöhringer³

2011

Zeitschrift Für Physikalische Chemie

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Vibrational Relaxation / Liquid Dynamics / Hydrogen-Bonding / Ultrafast SpectroscopyFemtosecond mid-infrared pump-probe spectroscopy was carried out to obtain information about the dynamics of vibrational energy relaxation in liquid ethanolamine at room temperature and ambient pressure. Through partial deuteration it was possible to disentangle the dynamics resulting from the OH and the NH stretching modes that proceed independently and simultaneously in the hydrogen-bonded liquid following an ultrafast vibrational excitation by a resonant mid-infrared pulse. The OH-stretching vibrational lifetime was determined to be 450 fs while the NH-stretching lifetime was found to be 1.2 ps. This large difference in lifetimes highlights the importance of the hydrogen-donating and the hydrogen-accepting character of the vibrating groups that are engaged in hydrogen-bonding.

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“…If we assume that the Nparticle probability density W N is approximated as a product of N spherical symmetric two-particle probability density functions: (18) where g(r) is the pair correlation function of intermolecular OH dipoles, we can simplify the part of intermolecular pathway of Eq. (15) in the thermodynamic limit where N,V → and N/V = ρ, 22,23,25 and we get the survival probability within the IPA as (19) where .…”

Section: Vibrational Energy Transfer In Watermentioning

confidence: 99%

“…(15), (19), and (20)] and the validities of them are assessed by comparing their predictions of survival probability with that of "exact" ME, Eq. (7), calculated by solving the master equation, Eq.…”

Section: Vibrational Energy Transfer In Watermentioning

confidence: 99%

“…Due to the couplings, when an OH bond is excited, the excited energy is transferred to nearby OH bonds which are resonant with the excited OH bond. The energy transfer process is manifested in spectroscopic data such as IR and Raman line shapes, 7,[12][13][14][15][16] vibrational pump-probe anisotropy, 14,[17][18][19] and two-dimensional surface vibrational spectroscopy. 20 The manifestation of energy transfer hinders one extracting the information about local spectral dynamics directly from the analysis of experimental results.…”

Section: Introductionmentioning

confidence: 99%

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Dynamics of Resonant Energy Transfer in OH Vibrations of Liquid Water

Yang¹

2012

Bulletin of the Korean Chemical Society

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Energy transfer dynamics of excited vibrational energy of OH stretching bonds in liquid water is theoretically studied. With time-dependent vibrational Hamiltonian obtained from a mixed quantum/classical calculation, we construct a master equation describing the energy transfer dynamics. Survival probability predicted by the master equation is compared with numerically exact one and we found that incoherent picture of energy transfer is reasonably valid for long-time population dynamics. Within the incoherent picture, we assess the validity of independent pair approximation (IPA) often introduced in the theoretical models utilized in the analysis of experimental data. Our results support that the IPA is almost perfectly valid as applied for the vibrational energy transfer in liquid water. However, proper incorporation of radial and orientational correlations between two OH bonds is found to be critical for a theory to be quantitatively valid. Consequently, it is suggested that the Förster model should be generalized by including the effects of the pair correlations in order to be applied for vibrational energy transfer in liquid water.

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Two-dimensional infrared spectroscopy and ultrafast anisotropy decay of water

Cited by 107 publications

References 45 publications

Hydration Dynamics of Aqueous Nitrate

Hydration Dynamics of Aqueous Nitrate

OH and NH Stretching Vibrational Relaxation of Liquid Ethanolamine

Dynamics of Resonant Energy Transfer in OH Vibrations of Liquid Water

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