Dynamics and critical damping of capillary waves in an ionic liquid

E. Sloutskin; P. Huber; M. Wolff; B. M. Ocko; A. Madsen; M. Sprung; V. Schön; J. Baumert; M. Deutsch

doi:10.1103/physreve.77.060601

Dynamics and critical damping of capillary waves in an ionic liquid

E. Sloutskin
, P. Huber
, M. Wolff
, B. M. Ocko
, A. Madsen
, M. Sprung
, V. Schön
, J. Baumert
, M. Deutsch

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

14 Scopus citations

Abstract

The dynamics of thermal capillary waves (CWs) on an ionic liquid's surface are studied at the transition from propagating to overdamped CWs by x-ray photon correlation spectroscopy. The analysis considers both homodyne and heterodyne contributions, and yields excellent full line-shape experiment-theory agreement for the structure factor. The CWs' Brillouin scattering becomes extinct at a critical temperature Tc JK ∼10 K above Tc LL, the propagating modes' hydrodynamic limit, in agreement with linear response theory. Surprisingly, the same power law applies at both Tc. The results rule out the presence of a suggested surface dipole layer.

Original language	English
Article number	060601
Journal	Physical Review E - Statistical, Nonlinear, and Soft Matter Physics
Volume	77
Issue number	6
DOIs	https://doi.org/10.1103/physreve.77.060601
State	Published - 3 Jun 2008

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10.1103/physreve.77.060601

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title = "Dynamics and critical damping of capillary waves in an ionic liquid",

abstract = "The dynamics of thermal capillary waves (CWs) on an ionic liquid's surface are studied at the transition from propagating to overdamped CWs by x-ray photon correlation spectroscopy. The analysis considers both homodyne and heterodyne contributions, and yields excellent full line-shape experiment-theory agreement for the structure factor. The CWs' Brillouin scattering becomes extinct at a critical temperature Tc JK ∼10 K above Tc LL, the propagating modes' hydrodynamic limit, in agreement with linear response theory. Surprisingly, the same power law applies at both Tc. The results rule out the presence of a suggested surface dipole layer.",

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T1 - Dynamics and critical damping of capillary waves in an ionic liquid

AU - Sloutskin, E.

AU - Huber, P.

AU - Wolff, M.

AU - Ocko, B. M.

AU - Madsen, A.

AU - Sprung, M.

AU - Schön, V.

AU - Baumert, J.

AU - Deutsch, M.

PY - 2008/6/3

Y1 - 2008/6/3

N2 - The dynamics of thermal capillary waves (CWs) on an ionic liquid's surface are studied at the transition from propagating to overdamped CWs by x-ray photon correlation spectroscopy. The analysis considers both homodyne and heterodyne contributions, and yields excellent full line-shape experiment-theory agreement for the structure factor. The CWs' Brillouin scattering becomes extinct at a critical temperature Tc JK ∼10 K above Tc LL, the propagating modes' hydrodynamic limit, in agreement with linear response theory. Surprisingly, the same power law applies at both Tc. The results rule out the presence of a suggested surface dipole layer.

AB - The dynamics of thermal capillary waves (CWs) on an ionic liquid's surface are studied at the transition from propagating to overdamped CWs by x-ray photon correlation spectroscopy. The analysis considers both homodyne and heterodyne contributions, and yields excellent full line-shape experiment-theory agreement for the structure factor. The CWs' Brillouin scattering becomes extinct at a critical temperature Tc JK ∼10 K above Tc LL, the propagating modes' hydrodynamic limit, in agreement with linear response theory. Surprisingly, the same power law applies at both Tc. The results rule out the presence of a suggested surface dipole layer.

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IS - 6

M1 - 060601

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Dynamics and critical damping of capillary waves in an ionic liquid

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