Broadband electromagnetic response and ultrafast dynamics of few-layer epitaxial graphene

Hyunyong Choi; F. Borondics; D. A. Siegel; Shou Yong Zhou; M. C. Martin; A. Lanzara; R. A. Kaindl

Broadband electromagnetic response and ultrafast dynamics of few-layer epitaxial graphene

Hyunyong Choi, F. Borondics, D. A. Siegel, Shou Yong Zhou, M. C. Martin, A. Lanzara, R. A. Kaindl

Department of Electrical and Electronic Engineering

Research output: Contribution to journal › Article › peer-review

221 Citations (Scopus)

Abstract

We study the broadband optical conductivity and ultrafast carrier dynamics of epitaxial graphene in the few-layer limit. Equilibrium spectra of nominally buffer, monolayer, and multilayer graphene exhibit significant terahertz and near-infrared absorption, consistent with a model of intra- and interband transitions in a dense Dirac electron plasma. Nonequilibrium terahertz transmission changes after photoexcitation are shown to be dominated by excess hole carriers, with a 1.2 ps monoexponential decay that reflects the minority-carrier recombination time.

Original language	English
Article number	172102
Journal	Applied Physics Letters
Publication status	Published - 2009 Apr

Cite this

@article{f856bfd2e9c3468287f9a1212ba28e9f,

title = "Broadband electromagnetic response and ultrafast dynamics of few-layer epitaxial graphene",

abstract = "We study the broadband optical conductivity and ultrafast carrier dynamics of epitaxial graphene in the few-layer limit. Equilibrium spectra of nominally buffer, monolayer, and multilayer graphene exhibit significant terahertz and near-infrared absorption, consistent with a model of intra- and interband transitions in a dense Dirac electron plasma. Nonequilibrium terahertz transmission changes after photoexcitation are shown to be dominated by excess hole carriers, with a 1.2 ps monoexponential decay that reflects the minority-carrier recombination time.",

author = "Hyunyong Choi and F. Borondics and Siegel, {D. A.} and Zhou, {Shou Yong} and Martin, {M. C.} and A. Lanzara and Kaindl, {R. A.}",

year = "2009",

month = apr,

language = "English",

journal = "Applied Physics Letters",

issn = "0003-6951",

publisher = "American Institute of Physics Publising LLC",

}

TY - JOUR

T1 - Broadband electromagnetic response and ultrafast dynamics of few-layer epitaxial graphene

AU - Choi, Hyunyong

AU - Borondics, F.

AU - Siegel, D. A.

AU - Zhou, Shou Yong

AU - Martin, M. C.

AU - Lanzara, A.

AU - Kaindl, R. A.

PY - 2009/4

Y1 - 2009/4

N2 - We study the broadband optical conductivity and ultrafast carrier dynamics of epitaxial graphene in the few-layer limit. Equilibrium spectra of nominally buffer, monolayer, and multilayer graphene exhibit significant terahertz and near-infrared absorption, consistent with a model of intra- and interband transitions in a dense Dirac electron plasma. Nonequilibrium terahertz transmission changes after photoexcitation are shown to be dominated by excess hole carriers, with a 1.2 ps monoexponential decay that reflects the minority-carrier recombination time.

AB - We study the broadband optical conductivity and ultrafast carrier dynamics of epitaxial graphene in the few-layer limit. Equilibrium spectra of nominally buffer, monolayer, and multilayer graphene exhibit significant terahertz and near-infrared absorption, consistent with a model of intra- and interband transitions in a dense Dirac electron plasma. Nonequilibrium terahertz transmission changes after photoexcitation are shown to be dominated by excess hole carriers, with a 1.2 ps monoexponential decay that reflects the minority-carrier recombination time.

M3 - Article

SN - 0003-6951

JO - Applied Physics Letters

JF - Applied Physics Letters

M1 - 172102

ER -

Broadband electromagnetic response and ultrafast dynamics of few-layer epitaxial graphene

Abstract

Fingerprint

Cite this