Ballistic transport in graphene beyond linear response

B. Rosenstein; M. Lewkowicz; H. C. Kao; Y. Korniyenko

doi:10.1103/PhysRevB.81.041416

Ballistic transport in graphene beyond linear response

B. Rosenstein, M. Lewkowicz, H. C. Kao, Y. Korniyenko

Department of Physics

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61 Scopus citations

Abstract

The process of coherent creation of particle-hole excitations by an electric field in graphene is quantitatively described beyond linear response. We calculate the evolution of current density, number of pairs and energy in ballistic regime for electric field E using the tight-binding model. While for ballistic flight times smaller than tnl E-1/2 current is linear in E and independent of time, for larger ballistic times the current increases after tnl as J E3/2 t and finally at yet larger times (t> tB E-1) Bloch oscillations set in. It is shown that the number of pairs follows the 2D generalization of the Schwinger's creation rate n E3/2 only on certain time segments with a prefactor different from that obtained using the asymptotic formula.

Original language	English
Article number	041416
Journal	Physical Review B - Condensed Matter and Materials Physics
Volume	81
Issue number	4
DOIs	https://doi.org/10.1103/PhysRevB.81.041416
State	Published - 29 Jan 2010

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title = "Ballistic transport in graphene beyond linear response",

abstract = "The process of coherent creation of particle-hole excitations by an electric field in graphene is quantitatively described beyond linear response. We calculate the evolution of current density, number of pairs and energy in ballistic regime for electric field E using the tight-binding model. While for ballistic flight times smaller than tnl E-1/2 current is linear in E and independent of time, for larger ballistic times the current increases after tnl as J E3/2 t and finally at yet larger times (t> tB E-1) Bloch oscillations set in. It is shown that the number of pairs follows the 2D generalization of the Schwinger's creation rate n E3/2 only on certain time segments with a prefactor different from that obtained using the asymptotic formula.",

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N2 - The process of coherent creation of particle-hole excitations by an electric field in graphene is quantitatively described beyond linear response. We calculate the evolution of current density, number of pairs and energy in ballistic regime for electric field E using the tight-binding model. While for ballistic flight times smaller than tnl E-1/2 current is linear in E and independent of time, for larger ballistic times the current increases after tnl as J E3/2 t and finally at yet larger times (t> tB E-1) Bloch oscillations set in. It is shown that the number of pairs follows the 2D generalization of the Schwinger's creation rate n E3/2 only on certain time segments with a prefactor different from that obtained using the asymptotic formula.

AB - The process of coherent creation of particle-hole excitations by an electric field in graphene is quantitatively described beyond linear response. We calculate the evolution of current density, number of pairs and energy in ballistic regime for electric field E using the tight-binding model. While for ballistic flight times smaller than tnl E-1/2 current is linear in E and independent of time, for larger ballistic times the current increases after tnl as J E3/2 t and finally at yet larger times (t> tB E-1) Bloch oscillations set in. It is shown that the number of pairs follows the 2D generalization of the Schwinger's creation rate n E3/2 only on certain time segments with a prefactor different from that obtained using the asymptotic formula.

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Ballistic transport in graphene beyond linear response

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