Interface Motion in Random Media

T. Bodineau; A. Teixeira

doi:10.1007/s00220-014-2152-4

Interface Motion in Random Media

T. Bodineau
, A. Teixeira

École Polytechnique

IMPA

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

Abstract

We study the pinning phase transition for discrete surface dynamics in random environments. A renormalization procedure is devised to prove that the interface moves with positive velocity under a finite size condition. This condition is then checked for different examples of microscopic dynamics to illustrate the flexibility of the method. We show in our examples the existence of a phase transition for various models, including high dimensional interfaces, dependent environments and environments with arbitrarily deep obstacles. Finally, our ballisticity criterion is proved to be valid up to the critical threshold for a Lipschitz interface model.

Original language	English
Pages (from-to)	843-865
Number of pages	23
Journal	Communications in Mathematical Physics
Volume	334
Issue number	2
DOIs	https://doi.org/10.1007/s00220-014-2152-4
Publication status	Published - 1 Mar 2015

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title = "Interface Motion in Random Media",

abstract = "We study the pinning phase transition for discrete surface dynamics in random environments. A renormalization procedure is devised to prove that the interface moves with positive velocity under a finite size condition. This condition is then checked for different examples of microscopic dynamics to illustrate the flexibility of the method. We show in our examples the existence of a phase transition for various models, including high dimensional interfaces, dependent environments and environments with arbitrarily deep obstacles. Finally, our ballisticity criterion is proved to be valid up to the critical threshold for a Lipschitz interface model.",

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AB - We study the pinning phase transition for discrete surface dynamics in random environments. A renormalization procedure is devised to prove that the interface moves with positive velocity under a finite size condition. This condition is then checked for different examples of microscopic dynamics to illustrate the flexibility of the method. We show in our examples the existence of a phase transition for various models, including high dimensional interfaces, dependent environments and environments with arbitrarily deep obstacles. Finally, our ballisticity criterion is proved to be valid up to the critical threshold for a Lipschitz interface model.

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Interface Motion in Random Media

Abstract

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