Interfacial Vibrational Dynamics of Ice Ihand Liquid Water

Prerna Sudera; Jenée D. Cyran; Malte Deiseroth; Ellen H.G. Backus; Mischa Bonn

doi:10.1021/jacs.0c04526

Interfacial Vibrational Dynamics of Ice I_hand Liquid Water

Prerna Sudera, Jenée D. Cyran, Malte Deiseroth, Ellen H.G. Backus, Mischa Bonn

Chemistry Department

Research output: Contribution to journal › Article › peer-review

15 Scopus citations

Abstract

Insights into energy flow dynamics at ice surfaces are essential for understanding chemical dynamics relevant to atmospheric and geographical sciences. Here, employing ultrafast surface-specific spectroscopy, we report the interfacial vibrational dynamics of ice Ih. A comparison to liquid water surfaces reveals accelerated vibrational energy relaxation and dissipation at the ice surface for hydrogen-bonded OH groups. In contrast, free-OH groups sticking into the vapor phase exhibit substantially slower vibrational dynamics on ice. The acceleration and deceleration of vibrational dynamics of these different OH groups at the ice surface are attributed to enhanced intermolecular coupling and reduced rotational mobility, respectively. Our results highlight the unique properties of free-OH groups on ice, putatively linked to the high catalytic activities of ice surfaces.

Original language	English
Pages (from-to)	12005-12009
Number of pages	5
Journal	Journal of the American Chemical Society
Volume	142
Issue number	28
DOIs	https://doi.org/10.1021/jacs.0c04526
State	Published - 15 Jul 2020

Keywords

energy
molecular dynamics
molecules
nonlinear optics
water

EGS Disciplines

Chemistry

Access to Document

10.1021/jacs.0c04526

Cyran, Jenee (2020) Interfacial vibrational dynamics - pub SelWrks.pdfFinal published version, 1.14 MBLicense: Unspecified

Cite this

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title = "Interfacial Vibrational Dynamics of Ice Ihand Liquid Water",

abstract = "Insights into energy flow dynamics at ice surfaces are essential for understanding chemical dynamics relevant to atmospheric and geographical sciences. Here, employing ultrafast surface-specific spectroscopy, we report the interfacial vibrational dynamics of ice Ih. A comparison to liquid water surfaces reveals accelerated vibrational energy relaxation and dissipation at the ice surface for hydrogen-bonded OH groups. In contrast, free-OH groups sticking into the vapor phase exhibit substantially slower vibrational dynamics on ice. The acceleration and deceleration of vibrational dynamics of these different OH groups at the ice surface are attributed to enhanced intermolecular coupling and reduced rotational mobility, respectively. Our results highlight the unique properties of free-OH groups on ice, putatively linked to the high catalytic activities of ice surfaces.",

keywords = "energy, molecular dynamics, molecules, nonlinear optics, water",

author = "Prerna Sudera and Cyran, {Jen{\'e}e D.} and Malte Deiseroth and Backus, {Ellen H.G.} and Mischa Bonn",

note = "Publisher Copyright: Copyright {\textcopyright} 2020 American Chemical Society.",

year = "2020",

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doi = "10.1021/jacs.0c04526",

language = "English",

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T1 - Interfacial Vibrational Dynamics of Ice Ihand Liquid Water

AU - Sudera, Prerna

AU - Cyran, Jenée D.

AU - Deiseroth, Malte

AU - Backus, Ellen H.G.

AU - Bonn, Mischa

PY - 2020/7/15

Y1 - 2020/7/15

N2 - Insights into energy flow dynamics at ice surfaces are essential for understanding chemical dynamics relevant to atmospheric and geographical sciences. Here, employing ultrafast surface-specific spectroscopy, we report the interfacial vibrational dynamics of ice Ih. A comparison to liquid water surfaces reveals accelerated vibrational energy relaxation and dissipation at the ice surface for hydrogen-bonded OH groups. In contrast, free-OH groups sticking into the vapor phase exhibit substantially slower vibrational dynamics on ice. The acceleration and deceleration of vibrational dynamics of these different OH groups at the ice surface are attributed to enhanced intermolecular coupling and reduced rotational mobility, respectively. Our results highlight the unique properties of free-OH groups on ice, putatively linked to the high catalytic activities of ice surfaces.

AB - Insights into energy flow dynamics at ice surfaces are essential for understanding chemical dynamics relevant to atmospheric and geographical sciences. Here, employing ultrafast surface-specific spectroscopy, we report the interfacial vibrational dynamics of ice Ih. A comparison to liquid water surfaces reveals accelerated vibrational energy relaxation and dissipation at the ice surface for hydrogen-bonded OH groups. In contrast, free-OH groups sticking into the vapor phase exhibit substantially slower vibrational dynamics on ice. The acceleration and deceleration of vibrational dynamics of these different OH groups at the ice surface are attributed to enhanced intermolecular coupling and reduced rotational mobility, respectively. Our results highlight the unique properties of free-OH groups on ice, putatively linked to the high catalytic activities of ice surfaces.

KW - energy

KW - molecular dynamics

KW - molecules

KW - nonlinear optics

KW - water

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