Experimental Observation of the Aubry Transition in Two-Dimensional Colloidal Monolayers

Experimental Observation of the Aubry Transition in Two-Dimensional Colloidal Monolayers

The possibility to achieve entirely frictionless, i.e., superlubric, sliding between solids holds enormous potential for the operation of mechanical devices. At small length scales, where mechanical contacts are well defined, Aubry predicted a transition from a superlubric to a pinned state when the...

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Main Authors: T. Brazda, A. Silva, N. Manini, A. Vanossi, R. Guerra, E. Tosatti, C. Bechinger
Format: Article
Language:English
Published: American Physical Society 2018-03-01
Series:Physical Review X
Online Access:http://doi.org/10.1103/PhysRevX.8.011050
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spelling doaj-572924b1c0954cf2b8b25c281b61833d2020-11-24T22:04:50ZengAmerican Physical SocietyPhysical Review X2160-33082018-03-018101105010.1103/PhysRevX.8.011050Experimental Observation of the Aubry Transition in Two-Dimensional Colloidal MonolayersT. BrazdaA. SilvaN. ManiniA. VanossiR. GuerraE. TosattiC. BechingerThe possibility to achieve entirely frictionless, i.e., superlubric, sliding between solids holds enormous potential for the operation of mechanical devices. At small length scales, where mechanical contacts are well defined, Aubry predicted a transition from a superlubric to a pinned state when the mechanical load is increased. Evidence for this intriguing Aubry transition (AT), which should occur in one dimension (1D) and at zero temperature, was recently obtained in few-atom chains. Here, we experimentally and theoretically demonstrate the occurrence of the AT in an extended two-dimensional (2D) system at room temperature using a colloidal monolayer on an optical lattice. Unlike the continuous nature of the AT in 1D, we observe a first-order transition in 2D leading to a coexistence regime of pinned and unpinned areas. Our data demonstrate that the original concept of Aubry not only survives in 2D but is relevant for the design of nanoscopic machines and devices at ambient temperature.http://doi.org/10.1103/PhysRevX.8.011050
collection DOAJ
language English
format Article
sources DOAJ
author T. Brazda
A. Silva
N. Manini
A. Vanossi
R. Guerra
E. Tosatti
C. Bechinger
spellingShingle T. Brazda
A. Silva
N. Manini
A. Vanossi
R. Guerra
E. Tosatti
C. Bechinger
Experimental Observation of the Aubry Transition in Two-Dimensional Colloidal Monolayers
Physical Review X
author_facet T. Brazda
A. Silva
N. Manini
A. Vanossi
R. Guerra
E. Tosatti
C. Bechinger
author_sort T. Brazda
title Experimental Observation of the Aubry Transition in Two-Dimensional Colloidal Monolayers
title_short Experimental Observation of the Aubry Transition in Two-Dimensional Colloidal Monolayers
title_full Experimental Observation of the Aubry Transition in Two-Dimensional Colloidal Monolayers
title_fullStr Experimental Observation of the Aubry Transition in Two-Dimensional Colloidal Monolayers
title_full_unstemmed Experimental Observation of the Aubry Transition in Two-Dimensional Colloidal Monolayers
title_sort experimental observation of the aubry transition in two-dimensional colloidal monolayers
publisher American Physical Society
series Physical Review X
issn 2160-3308
publishDate 2018-03-01
description The possibility to achieve entirely frictionless, i.e., superlubric, sliding between solids holds enormous potential for the operation of mechanical devices. At small length scales, where mechanical contacts are well defined, Aubry predicted a transition from a superlubric to a pinned state when the mechanical load is increased. Evidence for this intriguing Aubry transition (AT), which should occur in one dimension (1D) and at zero temperature, was recently obtained in few-atom chains. Here, we experimentally and theoretically demonstrate the occurrence of the AT in an extended two-dimensional (2D) system at room temperature using a colloidal monolayer on an optical lattice. Unlike the continuous nature of the AT in 1D, we observe a first-order transition in 2D leading to a coexistence regime of pinned and unpinned areas. Our data demonstrate that the original concept of Aubry not only survives in 2D but is relevant for the design of nanoscopic machines and devices at ambient temperature.
url http://doi.org/10.1103/PhysRevX.8.011050
work_keys_str_mv AT tbrazda experimentalobservationoftheaubrytransitionintwodimensionalcolloidalmonolayers
AT asilva experimentalobservationoftheaubrytransitionintwodimensionalcolloidalmonolayers
AT nmanini experimentalobservationoftheaubrytransitionintwodimensionalcolloidalmonolayers
AT avanossi experimentalobservationoftheaubrytransitionintwodimensionalcolloidalmonolayers
AT rguerra experimentalobservationoftheaubrytransitionintwodimensionalcolloidalmonolayers
AT etosatti experimentalobservationoftheaubrytransitionintwodimensionalcolloidalmonolayers
AT cbechinger experimentalobservationoftheaubrytransitionintwodimensionalcolloidalmonolayers
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