Unifying interfacial self-assembly and surface freezing

B. M. Ocko; H. Hlaing; P. N. Jepsen; S. Kewalramani; A. Tkachenko; D. Pontoni; H. Reichert; M. Deutsch

doi:10.1103/PhysRevLett.106.137801

Unifying interfacial self-assembly and surface freezing

B. M. Ocko
, H. Hlaing
, P. N. Jepsen
, S. Kewalramani
, A. Tkachenko
, D. Pontoni
, H. Reichert
, M. Deutsch

Department of Physics - at Bar-Ilan University

Brookhaven National Laboratory
European Synchrotron Radiation Facility

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

31 Scopus citations

Abstract

X-ray investigations reveal that the monolayers formed at the bulk alkanol-sapphire interface are densely packed with the surface-normal molecules hydrogen bound to the sapphire. About 30-35°C above the bulk, these monolayers both melt reversibly and partially desorb. This system exhibits balanced intermolecular and molecule-substrate interactions which are intermediate between self-assembled and surface-frozen monolayers, each dominated by one interaction. The phase behavior is rationalized within a thermodynamic model comprising interfacial interactions, elasticity, and entropic effects. Separating the substrate from the melt leaves the monolayer structurally intact.

Original language	English
Article number	137801
Journal	Physical Review Letters
Volume	106
Issue number	13
DOIs	https://doi.org/10.1103/PhysRevLett.106.137801
State	Published - 30 Mar 2011

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10.1103/PhysRevLett.106.137801

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title = "Unifying interfacial self-assembly and surface freezing",

abstract = "X-ray investigations reveal that the monolayers formed at the bulk alkanol-sapphire interface are densely packed with the surface-normal molecules hydrogen bound to the sapphire. About 30-35°C above the bulk, these monolayers both melt reversibly and partially desorb. This system exhibits balanced intermolecular and molecule-substrate interactions which are intermediate between self-assembled and surface-frozen monolayers, each dominated by one interaction. The phase behavior is rationalized within a thermodynamic model comprising interfacial interactions, elasticity, and entropic effects. Separating the substrate from the melt leaves the monolayer structurally intact.",

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AU - Ocko, B. M.

AU - Hlaing, H.

AU - Jepsen, P. N.

AU - Kewalramani, S.

AU - Tkachenko, A.

AU - Pontoni, D.

AU - Reichert, H.

AU - Deutsch, M.

PY - 2011/3/30

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AB - X-ray investigations reveal that the monolayers formed at the bulk alkanol-sapphire interface are densely packed with the surface-normal molecules hydrogen bound to the sapphire. About 30-35°C above the bulk, these monolayers both melt reversibly and partially desorb. This system exhibits balanced intermolecular and molecule-substrate interactions which are intermediate between self-assembled and surface-frozen monolayers, each dominated by one interaction. The phase behavior is rationalized within a thermodynamic model comprising interfacial interactions, elasticity, and entropic effects. Separating the substrate from the melt leaves the monolayer structurally intact.

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Unifying interfacial self-assembly and surface freezing

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