IR spectral assignments for the hydrated excess proton in liquid water

Biswas, Rajib; Carpenter, William Benjamin; Fournier, Joseph A.; Voth, Gregory A.; Tokmakoff, Andrei

doi:10.1063/1.4980121

Cited by 65 publications

(102 citation statements)

References 71 publications

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“…The broad featureless absorption at 2000–3000 cm –1 has been assigned to the OH-stretch vibrations of different proton hydration structures, whereas the absorption band observed at 1750 cm –1 is usually assigned to the bending vibrations of these structures. 31 − 33 …”

Section: Resultsmentioning

confidence: 99%

Slow Proton Transfer in Nanoconfined Water

Sofronov

Bakker

2020

ACS Cent. Sci.

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The transport of protons in nanoconfined environments, such as in nanochannels of biological or artificial proton conductive membranes, is essential to chemistry, biology, and nanotechnology. In water, proton diffusion occurs by hopping of protons between water molecules. This process involves the rearrangement of many hydrogen bonds and as such can be strongly affected by nanoconfinement. We study the vibrational and structural dynamics of hydrated protons in water nanodroplets stabilized by a cationic surfactant using polarization-resolved femtosecond infrared transient absorption spectroscopy. We determine the time scale of proton hopping in the center of the water nanodroplets from the dynamics of the anisotropy of the transient absorption signals. We find that in small nanodroplets with a diameter <4 nm, proton hopping is more than 10 times slower than in bulk water. Even in relatively large nanodroplets with a diameter of ∼7 nm, we find that the rate of proton hopping is slowed by ∼4 times compared with bulk water.

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Section: Resultsmentioning

confidence: 99%

Slow Proton Transfer in Nanoconfined Water

Sofronov

Bakker

2020

ACS Cent. Sci.

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“…Specifically, recent twodimensional (2D) IR experiments on hydrochloric (HCl) acid solutions probed a stretch-bend cross-peak and observed a timescale of 480 fs, which was interpreted as a lower bound on the Zundel complex lifetime 8 . While a) Electronic mail: tmarkland@stanford.edu this result suggests that certain proton defect structures interconvert over timescales longer than previously observed 7 , the interpretation of the cross-peak decay rested largely on assigning frequencies to the Zundel gas-phase structure within a cluster-centric paradigm 17,20,24,[27][28][29] . However, it remains unclear whether an interpretation of the liquid spectra based on the limiting Eigen and Zundel gas-phase cluster structures provides a complete picture of the structural motifs of condensed-phase proton defects and their interconversion timescales.…”

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confidence: 75%

Decoding the spectroscopic features and time scales of aqueous proton defects

Napoli

Maršálek

Markland

2018

The Journal of Chemical Physics

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Acid solutions exhibit a variety of complex structural and dynamical features arising from the presence of multiple interacting reactive proton defects and counterions. However, disentangling the transient structural motifs of proton defects in the water hydrogen bond network and the mechanisms for their interconversion remains a formidable challenge. Here, we use simulations treating the quantum nature of both the electrons and nuclei to show how the experimentally observed spectroscopic features and relaxation time scales can be elucidated using a physically transparent coordinate that encodes the overall asymmetry of the solvation environment of the proton defect. We demonstrate that this coordinate can be used both to discriminate the extremities of the features observed in the linear vibrational spectrum and to explain the molecular motions that give rise to the interconversion time scales observed in recent nonlinear experiments. This analysis provides a unified condensed-phase picture of the proton structure and dynamics that, at its extrema, encompasses proton sharing and spectroscopic features resembling the limiting Eigen [HO(HO)] and Zundel [H(HO)] gas-phase structures, while also describing the rich variety of interconverting environments in the liquid phase.

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“…42. We note that a broad, mid-IR continuum absorbance was also observed in a number of aqueous systems at ambient conditions, from protonated clusters (43) to bulk acidic solutions (44)(45)(46). An ultrafast 2D IR study of the excess protons in aqueous hydrochloric solutions (44) ascribed the broad-band intensity to vibrational modes of the Zundel and Eigen ions.…”

Section: [2]mentioning

confidence: 87%

Ab initio spectroscopy and ionic conductivity of water under Earth mantle conditions

Rozsa

Pan

Giberti

et al. 2018

Proc. Natl. Acad. Sci. U.S.A.

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The phase diagram of water at extreme conditions plays a critical role in Earth and planetary science, yet remains poorly understood. Here we report a first-principles investigation of the liquid at high temperature, between 11 GPa and 20 GPa-a region where numerous controversial results have been reported over the past three decades. Our results are consistent with the recent estimates of the water melting line below 1,000 K and show that on the 1,000-K isotherm the liquid is rapidly dissociating and recombining through a bimolecular mechanism. We found that short-lived ionic species act as charge carriers, giving rise to an ionic conductivity that at 11 GPa and 20 GPa is six and seven orders of magnitude larger, respectively, than at ambient conditions. Conductivity calculations were performed entirely from first principles, with no a priori assumptions on the nature of charge carriers. Despite frequent dissociative events, we observed that hydrogen bonding persists at high pressure, up to at least 20 GPa. Our computed Raman spectra, which are in excellent agreement with experiment, show no distinctive signatures of the hydronium and hydroxide ions present in our simulations. Instead, we found that infrared spectra are sensitive probes of molecular dissociation, exhibiting a broad band below the OH stretching mode ascribable to vibrations of complex ions.

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IR spectral assignments for the hydrated excess proton in liquid water

Cited by 65 publications

References 71 publications

Slow Proton Transfer in Nanoconfined Water

Slow Proton Transfer in Nanoconfined Water

Decoding the spectroscopic features and time scales of aqueous proton defects

Ab initio spectroscopy and ionic conductivity of water under Earth mantle conditions

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