Femtosecond Dynamics of Hydrogen Bonds in Liquid Water: A Real Time Study

Gale, G. M.; Gallot, Guilhem; Hache, F.; Lascoux, N.; Bratos, S.; Leicknam, J.-Cl.

doi:10.1103/physrevlett.82.1068

Cited by 320 publications

(366 citation statements)

References 16 publications

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“…The solution to the coupled rate equations for the population, N p , of photoproduct is (5) The long-time solution to eq 5 is Q = fN e (T w =0). The T w = 0 solution is 0.…”

Section: Hydrogen Bond Breakingmentioning

confidence: 99%

Watching Hydrogen Bonds Break: A Transient Absorption Study of Water

et al. 2004

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Ultrafast infrared transient absorption measurements of the complete hydroxyl OD stretching mode spectrum of HOD in water, from 100 fs to tens of picoseconds, observe hydrogen bond breaking and monitor the equilibration of the hydrogen bond network in water. In addition, the vibrational lifetime, the time constant for hydrogen bond breaking, and the rate of orientational relaxation are determined. The reactant and photoproduct spectra of the hydrogen bond breaking process are identified by decomposing the transient spectra into two components, the initial spectrum associated with vibrational excited states (reactants) and the long-time spectrum associated with broken hydrogen bonds (photoproducts). By properly taking into account the perturbation of the reactant spectrum decay by the growth of the photoproduct spectrum, it is found that the vibrational relaxation (1.45 ps) and orientational relaxation (1.53 ps) are wavelength independent and, therefore, independent of the degree of hydrogen bonding. Energy deposited into water by vibrational relaxation does not immediately break a hydrogen bond by predissociation nor produce a thermally equilibrated hydrogen bond distribution at an elevated temperature. Following deposition of energy by vibrational relaxation, the hydrogen bond breaking time is 800 fs, and there is a transient period of several picoseconds during which the hydrogen bond distribution is not in thermal equilibrium.

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“…The solution to the coupled rate equations for the population, N p , of photoproduct is (5) The long-time solution to eq 5 is Q = fN e (T w =0). The T w = 0 solution is 0.…”

Section: Hydrogen Bond Breakingmentioning

confidence: 99%

Watching Hydrogen Bonds Break: A Transient Absorption Study of Water

et al. 2004

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“…Nonlinear vibrational spectroscopy, such as two dimensional infrared spectroscopy (2D IR) [26][27][28][29][30][31][32][33], is an excellent tool to monitor the local structure and dynamical properties of the hydrogen bonds in water. These experiments make use of the fact that the vibrational frequency of the OH stretch vibration is highly correlated with the OO distance of a pair of hydrogen bonded water molecules [34][35][36][37][38]. That is, a shorter and therefore stronger hydrogen bond results in a larger red shift of the OH stretch vibration.…”

Section: Introductionmentioning

confidence: 99%

Two-Dimensional Infrared Spectroscopy of Isotope-Diluted Low Density Amorphous Ice

2013

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We present two-dimensional (2D) infrared (IR) spectra of isotope diluted ice in its low density amorphous form. Amorphous ice, which is structurally more similar to liquid water than to crystalline ice, provides higher resolution spectra of the hydrogen bond potentials because all motion is frozen. In the case of OD vibration of HOD in H2O, diagonal and off-diagonal (intermode) anharmonicity as well as the relaxation rate of the first excited state increase with hydrogen bond strength in a consistent way. For the OH vibration of HOD in D2O, additional more specific couplings need to be taken into account to explain the 2D IR response, that is, a Fermi resonance with the HOD bend vibration and couplings to phonon modes that lead to quantum beating. The lifetime of the fist excited state, 240 fs, is the shortest ever reported for any phase of isotope diluted water. We present 2D IR spectra of isotope diluted ice in its low density amorphous form. Amorphous ice, which is structurally more similar to liquid water than to crystalline ice, provides higher resolution spectra of the hydrogen bond potentials because all motion is frozen. In the case of OD vibration of HOD in H2O, diagonal and off-diagonal (inter-mode) anharmonicity as well as the relaxation rate of the first excited state increases with hydrogen bond strength in a consistent way. For the OH vibration of HOD in D2O, additional more specific couplings need to be taken into account to explain the 2D IR response, that is, a Fermi resonance with the HOD bend vibration and couplings to phonon modes that lead to quantum beating. The lifetime of the fist excited state, 240 fs, is the shortest ever reported for any phase of isotope diluted water.

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“…Static x-ray spectroscopy has revealed quantitative information on local atomic structure 4,5 whereas time-resolved vibrational spectroscopy has produced information on timescales of structural dynamics as short as 50fs. 6,7,8,9 Time-resolved vibrational spectroscopy has concentrated on the infrared spectrum of HOD in D 2 O and H 2 O 10,11,12,13,14,15,16 and to a lesser extent on pure H 2 O, 17,18 limited by the (sub-)micron absorption length. The latter also poses a challenge for x-ray absorption spectroscopy.…”

Section: Introductionmentioning

confidence: 99%

Probing the hydrogen-bond network of water via time-resolved soft X-ray spectroscopy

Huse

Wen

Nordlund

et al. 2009

Phys. Chem. Chem. Phys.

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We report time-resolved studies of hydrogen bonding in liquid H 2 O, in response to direct excitation of the O-H stretch mode at 3 µm, probed via soft x-ray absorption spectroscopy at the oxygen K-edge. This approach employs a newly developed nanofluidic cell for transient soft x-ray spectroscopy in liquid phase. Distinct changes in the near-edge spectral region (XANES) are observed, and are indicative of a transient temperature rise of 10K following transient laser excitation and rapid thermalization of vibrational energy. The rapid heating occurs at constant volume and the associated increase in internal pressure, estimated to be 8MPa, is manifest by distinct spectral changes that differ from those induced by temperature alone. We conclude that the near-edge spectral shape of the oxygen K-edge is a sensitive probe of internal pressure, opening new possibilities for testing the validity of water models and providing new insight into the nature of hydrogen bonding in water.

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Femtosecond Dynamics of Hydrogen Bonds in Liquid Water: A Real Time Study

Cited by 320 publications

References 16 publications

Watching Hydrogen Bonds Break: A Transient Absorption Study of Water

Watching Hydrogen Bonds Break: A Transient Absorption Study of Water

Two-Dimensional Infrared Spectroscopy of Isotope-Diluted Low Density Amorphous Ice

Probing the hydrogen-bond network of water via time-resolved soft X-ray spectroscopy

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