Water-anion hydrogen bonding dynamics: Ultrafast IR experiments and simulations

Yamada, Steven A.; Thompson, Ward H.; Fayer, M. D.

doi:10.1063/1.4984766

Cited by 40 publications

(136 citation statements)

References 72 publications

(141 reference statements)

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“…The reorientation of water along the OH bond vector is more sensitive to anion than cation due to the direct hydrogen bond between anion and the water hydrogen. Cations, on the other hand, limit the reorientation of the water dipoles, especially for the divalence and trivalence ones (Boisson et al, 2011;Buchner et al, 2004;Buchner & Hefter, 2009;Laage & Hynes, 2007, 2008b; Lin, Auer, & Skinner, 2009;Park & Fayer, 2007;Turton et al, 2008;Wachter et al, 2007;Yamada, Thompson, & Fayer, 2017;R. Zhang & Zhuang, 2013).…”

Section: Water Reorientation Dynamics Probed By Spectroscopic Techniquesmentioning

confidence: 99%

Ion effect on the dynamics of water hydrogen bonding network: A theoretical and computational spectroscopy point of view

Zhang

et al. 2018

WIREs Comput Mol Sci

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Understanding the elementary hydration dynamics of the ions and their couplings with the aqueous environments is important for researches in fields including energy, molecular biology, biomedical sciences, and chemical reactions. The concept of hydration shell is ubiquitously used to rationalize the differences of water behavior near the ions with respect to those in the bulk water. One intriguing issue, however, is to decide the spatial range of these hydration shells. Different experimental spectroscopic techniques such as the femtosecond infrared at high frequency and optical Kerr effect, dielectric relaxation, as well as terahertz measurements at low frequency often give controversial indications on this matter. As the optical transition observables provided by the spectroscopic measurements only indirectly reflect the realspace structure and dynamics information, the theoretical modeling of these signals is often desired in order to reveal the underlying physics in each of these measurements, and to understand the aforementioned apparent controversy. In this review, we outline recent progresses in the theoretical modeling of water dynamics around the ions and ionic moieties and the related vibrational spectroscopy, especially on the femtosecond infrared related single molecular water reorientation and the lowfrequency vibrational spectra related collective water dynamics. This article is categorized under: Theoretical and Physical Chemistry > Spectroscopy Theoretical and Physical Chemistry > Statistical Mechanics K E Y W O R D S hydrogen bond relaxation, ion effect, ionic solution, jump reorientation, molecular dynamic simulation, nonlinear spectroscopy

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Section: Water Reorientation Dynamics Probed By Spectroscopic Techniquesmentioning

confidence: 99%

Ion effect on the dynamics of water hydrogen bonding network: A theoretical and computational spectroscopy point of view

Zhang

et al. 2018

WIREs Comput Mol Sci

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“…For SeCN -, the electric field at the position of the C projected onto the CN bond-vector does accurately predict the C − − − N stretching frequency, but this is largely due to a cancellation of effects. 26 Nevertheless, this phenomenological association of local electric field with vibrational frequency still strongly supports the concept that the vibrational frequency will be sensitive to molecular orientation.…”

Section: Temperature-dependent Spectral Diffusion Dynamicsmentioning

confidence: 65%

“…Theoretical work has shown that both electrostatics beyond the dipole approximation and chemical interactions like charge transfer play important roles in determining the C − − − N stretching frequency. 26,58,59 Nevertheless, if these interactions are vectorial in nature, i.e. they depend on the orientation of the molecule, then they can be incorporated into the conceptual framework of RISD.…”

Section: Temperature-dependent Spectral Diffusion Dynamicsmentioning

confidence: 99%

“…42 Furthermore, a combination of MD simulations and ultrafast infrared spectroscopy developed a spectroscopic map of SeCNin D 2 O that describes the frequency dependence of the nitrile stretch to a hydrogen bonding environment. 26 2D-IR spectroscopy can report two-point correlations in vibrational frequency and orientation. The shapes of 2D-IR spectra and how they change encode the frequency fluctuations of IR chromophores -the frequency fluctuation correlation function (FFCF).…”

Section: Introductionmentioning

confidence: 99%

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An Ultrafast Vibrational Study of Dynamical Heterogeneity in the Protic Ionic Liquid Ethyl-Ammonium Nitrate

Johnson

Parker²,

Donaldson³

et al. 2019

Preprint

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Using ultrafast two-dimensional infrared spectroscopy (2D-IR), a vibrational probe (thiocyanate, SCN-) was used to investigate the hydrogen bonding network of a molten salt (ethyl-ammonium nitrate, EAN) compared to that of H2O. The 2D-IR experiments were performed in both parallel () and perpendicular () conditions along with temperature dependence for both EAN (14-130 ˚C) and H2O (5-89 ˚C). With polarization control, the frequency fluctuation correlation function can be separated into structural and rotational components. An Arrhenius analysis lead to independent activation energies for the isotropic, and anisotropic signals, structural spectral diffusion, and rotational induced spectral diffusion. The rotational Eas were similar for both EAN and H2O suggesting that SCN- is experiencing a similar jump model, i.e. where hydrogen bond reorientation is dominated by large angular jumps stemming from molecular rotation dynamics. The frequency pre-factors, however, were different where the more rigid and vicious EAN had a slower rate. Furthermore, the 2D-IR anisotropy and vibrational relaxation rates of EAN are frequency dependent, revealing that SCN- experiences two subensembles. We suggest that the sub-ensemble with a faster rotational timescale correlates to SCN- with more, weaker hydrogen bonds, and the sub-ensemble with a slower rotational timescale correlates to SCN- with a stronger, more directional hydrogen bond.

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“…[18] Likewise,t he longest memory of inhomogeneity of the very strongly H-bonded excess proton in water, [19] was recently found to be only of the order of 200 fs. [18] Likewise,t he longest memory of inhomogeneity of the very strongly H-bonded excess proton in water, [19] was recently found to be only of the order of 200 fs.…”

Section: Angewandte Chemiementioning

confidence: 99%

Transient Glass Formation around a Quadrupolar Photoexcited Dye in a Strongly H‐Bonding Liquid Observed by Transient 2D‐IR Spectroscopy

2018

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Intermolecular H-bonding dynamics around aphotoexcited quadrupolar dye is directly observed using transient 2D-IR spectroscopy. Upon solvent-induced symmetry breaking, the H-bond accepting abilities of the two nitrile end-groups change drastically,a nd in extremely protic (superprotic) solvents,atight H-bond complex forms at one end. The time evolution of the 2D C Nlineshape in methanol points to rapid, 2-3 ps,spectral diffusion due to fluctuations of the H-bonding network. Similar behavior is observed in asuperprotic solvent shortly after photoexcitation of the dye.However,atlater times, the completely inhomogeneous band does not exhibit spectral diffusion for at least 5ps, pointing to aglass-like environment around one side of the dye.About half of the excited dyes show this behavior attributed to the tight H-bond complex, whereas the others are loosely bound. Aw eak cross peak indicates partial exchange between these excited state subpopulations.

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Water-anion hydrogen bonding dynamics: Ultrafast IR experiments and simulations

Cited by 40 publications

References 72 publications

Ion effect on the dynamics of water hydrogen bonding network: A theoretical and computational spectroscopy point of view

Ion effect on the dynamics of water hydrogen bonding network: A theoretical and computational spectroscopy point of view

An Ultrafast Vibrational Study of Dynamical Heterogeneity in the Protic Ionic Liquid Ethyl-Ammonium Nitrate

Transient Glass Formation around a Quadrupolar Photoexcited Dye in a Strongly H‐Bonding Liquid Observed by Transient 2D‐IR Spectroscopy

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