On the Photoionization Mechanism of Liquid Water

Sander, M.; Luther, K.; Troe, J.

doi:10.1002/bbpc.19930970802

Cited by 87 publications

(58 citation statements)

References 65 publications

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“…Actually in LRG, almost all ionized electrons can be collected by a modest external field, a fact which is of great importance in the operation of large ionization chambers (Doke, 1981 By contrast, even the primary ionization and excitation processes in polar liquids seem to be different from their gas-phase counterparts, in view of recent experimental and theoretical findings (Sander et al, 1993a, b;Bartels and Crowell, 2000;Mozumder, 2002a). Accordingly, the low-energy processes, down to $6.5 eV, giving a small yield of e À aq ; are due to neither direct nor autoionization, but to optical charge transfer or to photoinduced electron transfer as the energy is increased (Sander et al, 1993a). A concerted proton-coupled electron transfer mechanism, first proposed by Keszei and Jay-Gerin (1992), has support in the experiments of Bartels and Crowell (2000) up to $9.3 eV, while Sander et al (1993a, b) suggest that quasi-free electrons may not be produced until the band gap energy ($10-12 eV) is reached.…”

Section: Ionization In the Condensed Phasementioning

confidence: 85%

Electrons in condensed media

Mozumder

2005

Radiation Physics and Chemistry

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Section: Ionization In the Condensed Phasementioning

confidence: 85%

Electrons in condensed media

Mozumder

2005

Radiation Physics and Chemistry

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“…1(b) and (c)]. This indicates that excitation into the CB becomes possible in an "autoionization" process, which involves reorganization of the excited water molecule into a form with lower ionization potential [30,31,41,45,48]. Above the threshold for vertical ionization, where nuclear position remain unchanged, the electron ejection length finally reaches a value of about 4 nm [30,49] [ Fig.…”

Section: Part Of the Solvated Electronsmentioning

confidence: 99%

Wavelength dependence of nanosecond infrared laser-induced breakdown in water: Evidence for multiphoton initiation via an intermediate state

et al. 2015

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Investigation of the wavelength dependence (725 -1025 nm) of the threshold for nanosecond optical breakdown in water revealed steps consistent with breakdown initiation by multiphoton ionization, with an initiation energy of about 6.6 eV. This value is considerably smaller than the autoionization threshold of about 9.5 eV, which can be regarded as band gap relevant for avalanche ionization. Breakdown initiation is likely to occur via excitation of a valence band electron into a solvated state, followed by rapid excitation into the conduction band. Theoretical analysis based on these assumptions suggests that the seed electron density required for initiating avalanche ionization drops from 2.5×10 15 cm -3 at 725 nm to 1.1×10 12 cm -3 at 1025 nm. These results demand changes of future breakdown modeling for water including the use of a larger band gap than previously employed, the introduction of an intermediate energy level for initiation, and consideration of the wavelength dependence of seed electron density.

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“…It is generally accepted that there are at least two photoionization pathways for the excess electron. 2,3,5,6 That is, if the excitation energy is large enough (>9.8-9.9 eV), 3 the electron can reach the conduction band of water directly and vertically. At energies below, a concerted nuclear rearrangement or a coincidentally pre-arranged minimum on the potential surface are required for the detachment process to occur.…”

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confidence: 99%

Note: Deep UV-pump THz-probe spectroscopy of the excess electron in water

Berger

Savolainen

Shalit

et al. 2017

The Journal of Chemical Physics

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In the work of Savolainen et al. [Nat. Chem. 6, 697 (2014)], we studied the excess (hydrated) electron in water with the help of transient THz spectroscopy, which is a sensitive probe of its delocalization length. In that work, we used laser pulses at 800 nm, 400 nm, and 267 nm for photoionization. While the detachment mechanism for 400 nm and 267 nm is complicated and requires a concerted nuclear rearrangement, we provided evidence that 800 nm pumping excites the excess electron directly and vertically into the conduction band, despite a highly nonlinear field-ionization process. In the present note, we extend that work to 200 nm pumping, which provides a much cleaner way to reach the conduction band. We show that the detachment pathways upon 200 nm and 800 nm pumping are in essence the same, as indicated by the same initial size of the electron wavefunction and the same time scales for the collapse of the wavefunction and geminate recombination.

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On the Photoionization Mechanism of Liquid Water

Cited by 87 publications

References 65 publications

Electrons in condensed media

Electrons in condensed media

Wavelength dependence of nanosecond infrared laser-induced breakdown in water: Evidence for multiphoton initiation via an intermediate state

Note: Deep UV-pump THz-probe spectroscopy of the excess electron in water

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