W.-H. Kim scite author profile

W.-H. Kim

2Publications

123Citation Statements Received

16Citation Statements Given

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Ames Laboratory, Iowa State University

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Hyperquenched glassy films of water: A study by hole burning

Kim¹,

Reinot²,

Hayes³

et al. 1995

J. Phys. Chem.

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The results of infrared absorption (-OH) experiments and nonphotochemical hole-burning experiments of aluminum-phthalocyanine-tetrasulfonate (ATP) in hyperquenched glassy films of water (HGW) are reported. Films were produced by deposition of liquid water clusters (-2 pm), generated by a thermal spray nozzle source, onto either a sapphire or polycrystalline copper cryoplate. Deposition temperatures (TD) in the -5-150 K range were employed. TD = 5 K films were annealed at various temperatures (TA), up to 140 K. For each value of TA, the infrared and hole-burning properties (zero-phonon hole width and hole growth kinetics) of the film (annealed) are identical to those of unannealed HGW formed at TD = TA. Thus, HGW formed at a deposition temperature of TD' is kinetically accessible, by annealing of HGW formed at temperatures TD < To'. Dramatic irreversible manifestations of configurational relaxation in HGW are observed to onset at TA (TD) -90 K. This configurational relaxation progresses smoothly with temperature up to 150 K (highest TD and TA used). Zero-phonon hole widths were usually determined for a burning and reading temperature of 5 K. Hole growth kinetics were always monitored at a burning temperature of 5 K. It was found, for example, that HGW annealed or deposited at 140 K yields a zero-phonon hole width of 180 MHz, a factor of 3 times narrower than the hole of HGW formed at TD = 5 K. Decrease of the hole width with annealing onsets at TA -90 K. Both unannealed and annealed films yielded a power law for the dependence of the hole width on the burning temperature (5 10 K), proving that pure dephasinghpectral diffusion is governed by the electron-TLSint (intrinsic two-level systems) interaction. An interpretation of the aforementioned configuration relaxation, onsetting at -90 K, in terms of the TLSint model is given. ATP in HGW turns out to be the most efficient system for nonphotochemical hole burning yet discovered, with an average quantum yield as high as 0.18. (The SI lifetime of ATP is 4.8 ns.) Remarkably, the hole burning is essentially inoperative in cubic ice formed by warming of HGW. However, this cessation is consistent with the current mechanism for nonphotochemical hole burning.

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Erratum: Electronic dephasing of APT in glassy films of water from 5 to 100 K: Implications for H-bonding liquids [J. Chem. Phys. 104, 793 (1996)]

Reinot

Kim

Hayes

et al. 1997

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W.-H. Kim

Hyperquenched glassy films of water: A study by hole burning

Erratum: Electronic dephasing of APT in glassy films of water from 5 to 100 K: Implications for H-bonding liquids [J. Chem. Phys. 104, 793 (1996)]

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