Wiedemann–Franz Law for Massless Dirac Fermions with Implications for Graphene

Wiedemann–Franz Law for Massless Dirac Fermions with Implications for Graphene

In the 2016 experiment by Crossno et al. the electronic contribution to the thermal conductivity of graphene was found to violate the well-known Wiedemann–Franz (WF) law for metals. At liquid nitrogen temperatures, the thermal to electrical conductivity ratio of charge-neutral samples was more than...

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Veröffentlicht in:Materials 2021-05, Vol.14 (11), p.2704
1. Verfasser: Rycerz, Adam
Format: Artikel
Sprache:eng
Schlagworte:
Approximation
Computational fluid dynamics
Electrical resistivity
Energy
Fermions
Fluid flow
Gases
Graphene
Heat conductivity
Heat transfer
Hydrodynamics
Liquid nitrogen
Metals
Temperature
Thermal conductivity
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Zusammenfassung:In the 2016 experiment by Crossno et al. the electronic contribution to the thermal conductivity of graphene was found to violate the well-known Wiedemann–Franz (WF) law for metals. At liquid nitrogen temperatures, the thermal to electrical conductivity ratio of charge-neutral samples was more than 10 times higher than predicted by the WF law, which was attributed to interactions between particles leading to collective behavior described by hydrodynamics. Here, we show, by adapting the handbook derivation of the WF law to the case of massless Dirac fermions, that significantly enhanced thermal conductivity should appear also in few- or even sub-kelvin temperatures, where the role of interactions can be neglected. The comparison with numerical results obtained within the Landauer–Büttiker formalism for rectangular and disk-shaped (Corbino) devices in ballistic graphene is also provided.
ISSN:1996-1944
1996-1944
DOI:10.3390/ma14112704