Modelling Spontaneous Thermal Fluctuations of Ripples in Suspended Graphene
ORAL
Abstract
At room temperature, micron-size sheets of freestanding graphene are in constant motion, even in the presence of an applied
bias voltage. A key mechanism behind this result is the stochastic curvature inversion of ripples, during which thousands of atoms move
coherently with long-time correlations. We present a Langevin model that captures this out-of-plane motion unique to two-dimensional
materials. In particular, we model the membrane atoms closer to the scanning tunneling microscopy tip as a Brownian particle in a double-well potential, which represents the convex and concave curvature states of the ripple. In addition, we compute the average generated power using the stochastic thermodynamics formalism.
bias voltage. A key mechanism behind this result is the stochastic curvature inversion of ripples, during which thousands of atoms move
coherently with long-time correlations. We present a Langevin model that captures this out-of-plane motion unique to two-dimensional
materials. In particular, we model the membrane atoms closer to the scanning tunneling microscopy tip as a Brownian particle in a double-well potential, which represents the convex and concave curvature states of the ripple. In addition, we compute the average generated power using the stochastic thermodynamics formalism.
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Presenters
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Antonio Lasanta Becerra
Univ de Granada, Álgebra, Univ de Granada, Universidad de Granada, Álgebra, Universidad de Granada
Authors
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Antonio Lasanta Becerra
Univ de Granada, Álgebra, Univ de Granada, Universidad de Granada, Álgebra, Universidad de Granada
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Luis Bonilla
Universidad Carlos III de Madrid, Univ Carlos III De Madrid
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Paul M Thibado
University of Arkansas
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Pradeep Kumar
University of Arkansas
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Surendra Pal Singh
University of Arkansas
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Miguel Ruiz Garcia
Technical University of Madrid, University of Pennsylvania