Casimir force phase transitions in the graphene family

The Casimir force is a universal interaction induced by electromagnetic quantum fluctuations between any types of objects. The expansion of the graphene family by adding silicene, germanene and stanene (2D allotropes of Si, Ge, and Sn), lends itself as a platform to probe Dirac-like physics in honey...

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Veröffentlicht in:Nature communications Jg. 8; H. 1; S. 14699
Hauptverfasser: Rodriguez-Lopez, Pablo, Kort-Kamp, Wilton J. M., Dalvit, Diego A. R., Woods, Lilia M.
Format: Journal Article
Sprache:Englisch
Veröffentlicht: London Nature Publishing Group UK 15.03.2017
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Casimir Interactions, Graphene, Silicene, Hall Effects
Electrons
Graphene
Humanities and Social Sciences
MATERIALS SCIENCE
multidisciplinary
Phase transitions
Physics
Science
Science (multidisciplinary)
Temperature effects
New Mexico
United States > US
ISSN:2041-1723, 2041-1723
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Abstract The Casimir force is a universal interaction induced by electromagnetic quantum fluctuations between any types of objects. The expansion of the graphene family by adding silicene, germanene and stanene (2D allotropes of Si, Ge, and Sn), lends itself as a platform to probe Dirac-like physics in honeycomb staggered systems in such a ubiquitous interaction. We discover Casimir force phase transitions between these staggered 2D materials induced by the complex interplay between Dirac physics, spin-orbit coupling and externally applied fields. In particular, we find that the interaction energy experiences different power law distance decays, magnitudes and dependences on characteristic physical constants. Furthermore, due to the topological properties of these materials, repulsive and quantized Casimir interactions become possible. The Casimir force is a ubiquitous interaction arising from electromagnetic quantum fluctuations. Here, the authors uncover the underlying physics governing Casimir force phase transitions in staggered 2D materials in the graphene family.
AbstractList The Casimir force is a universal interaction induced by electromagnetic quantum fluctuations between any types of objects. The expansion of the graphene family by adding silicene, germanene and stanene (2D allotropes of Si, Ge, and Sn), lends itself as a platform to probe Dirac-like physics in honeycomb staggered systems in such a ubiquitous interaction. We discover Casimir force phase transitions between these staggered 2D materials induced by the complex interplay between Dirac physics, spin-orbit coupling and externally applied fields. In particular, we find that the interaction energy experiences different power law distance decays, magnitudes and dependences on characteristic physical constants. Furthermore, due to the topological properties of these materials, repulsive and quantized Casimir interactions become possible.
The Casimir force is a ubiquitous interaction arising from electromagnetic quantum fluctuations. Here, the authors uncover the underlying physics governing Casimir force phase transitions in staggered 2D materials in the graphene family.
The Casimir force is a universal interaction induced by electromagnetic quantum fluctuations between any types of objects. The expansion of the graphene family by adding silicene, germanene and stanene (2D allotropes of Si, Ge, and Sn), lends itself as a platform to probe Dirac-like physics in honeycomb staggered systems in such a ubiquitous interaction. We discover Casimir force phase transitions between these staggered 2D materials induced by the complex interplay between Dirac physics, spin-orbit coupling and externally applied fields. In particular, we find that the interaction energy experiences different power law distance decays, magnitudes and dependences on characteristic physical constants. Furthermore, due to the topological properties of these materials, repulsive and quantized Casimir interactions become possible. The Casimir force is a ubiquitous interaction arising from electromagnetic quantum fluctuations. Here, the authors uncover the underlying physics governing Casimir force phase transitions in staggered 2D materials in the graphene family.
The Casimir force is a universal interaction induced by electromagnetic quantum fluctuations between any types of objects. The expansion of the graphene family by adding silicene, germanene and stanene (2D allotropes of Si, Ge, and Sn), lends itself as a platform to probe Dirac-like physics in honeycomb staggered systems in such a ubiquitous interaction. We discover Casimir force phase transitions between these staggered 2D materials induced by the complex interplay between Dirac physics, spin-orbit coupling and externally applied fields. In particular, we find that the interaction energy experiences different power law distance decays, magnitudes and dependences on characteristic physical constants. Furthermore, due to the topological properties of these materials, repulsive and quantized Casimir interactions become possible. The Casimir force is a ubiquitous interaction arising from electromagnetic quantum fluctuations. Here, the authors uncover the underlying physics governing Casimir force phase transitions in staggered 2D materials in the graphene family.
The Casimir force is a universal interaction induced by electromagnetic quantum fluctuations between any types of objects. We found that the expansion of the graphene family by adding silicene, germanene and stanene (2D allotropes of Si, Ge, and Sn), lends itself as a platform to probe Dirac-like physics in honeycomb staggered systems in such a ubiquitous interaction. Here, we discover Casimir force phase transitions between these staggered 2D materials induced by the complex interplay between Dirac physics, spin-orbit coupling and externally applied fields. Particularly, we find that the interaction energy experiences different power law distance decays, magnitudes and dependences on characteristic physical constants. Furthermore, due to the topological properties of these materials, repulsive and quantized Casimir interactions become possible.
ArticleNumber 14699
Author Kort-Kamp, Wilton J. M.
Woods, Lilia M.
Rodriguez-Lopez, Pablo
Dalvit, Diego A. R.
Author_xml – sequence: 1
  givenname: Pablo
  surname: Rodriguez-Lopez
  fullname: Rodriguez-Lopez, Pablo
  organization: Department of Physics, University of South Florida
– sequence: 2
  givenname: Wilton J. M.
  surname: Kort-Kamp
  fullname: Kort-Kamp, Wilton J. M.
  organization: Center for Nonlinear Studies, MS B258, Los Alamos National Laboratory, Theoretical Division, MS B213, Los Alamos National Laboratory
– sequence: 3
  givenname: Diego A. R.
  surname: Dalvit
  fullname: Dalvit, Diego A. R.
  email: dalvit@lanl.gov
  organization: Theoretical Division, MS B213, Los Alamos National Laboratory
– sequence: 4
  givenname: Lilia M.
  surname: Woods
  fullname: Woods, Lilia M.
  email: lmwoods@usf.edu
  organization: Department of Physics, University of South Florida
BackLink https://www.ncbi.nlm.nih.gov/pubmed/28294111$$D View this record in MEDLINE/PubMed
https://www.osti.gov/servlets/purl/1357120$$D View this record in Osti.gov
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Snippet The Casimir force is a universal interaction induced by electromagnetic quantum fluctuations between any types of objects. The expansion of the graphene family...
The Casimir force is a universal interaction induced by electromagnetic quantum fluctuations between any types of objects. We found that the expansion of the...
The Casimir force is a ubiquitous interaction arising from electromagnetic quantum fluctuations. Here, the authors uncover the underlying physics governing...
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SubjectTerms 639/301/357
639/624/399/918/1054
639/766/119
Casimir Interactions, Graphene, Silicene, Hall Effects
Electrons
Graphene
Humanities and Social Sciences
MATERIALS SCIENCE
multidisciplinary
Phase transitions
Physics
Science
Science (multidisciplinary)
Temperature effects
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Title Casimir force phase transitions in the graphene family
URI https://link.springer.com/article/10.1038/ncomms14699
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