Open AccessFour-Wave Mixing in Landau-Quantized Graphene
Author(s) -
Jacob C Koenig-Otto,
Yongrui Wang,
Alexey Belyanin,
Claire C Berger,
Walt A. de Heer,
M. Orlita,
Alexej Pashkin,
H. Schneider,
M. Helm,
Stephan Winnerl
Publication year - 2017
Publication title -
nano letters
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 4.853
H-Index - 488
eISSN - 1530-6992
pISSN - 1530-6984
DOI - 10.1021/acs.nanolett.6b04665
Subject(s) - physics , dephasing , landau quantization , four wave mixing , degenerate energy levels , condensed matter physics , graphene , nonlinear system , population , polarization (electrochemistry) , quantum mechanics , nonlinear optics , magnetic field , chemistry , demography , sociology
For Landau-quantized graphene, featuring an energy spectrum consisting of nonequidistant Landau levels, theory predicts a giant resonantly enhanced optical nonlinearity. We verify the nonlinearity in a time-integrated degenerate four-wave mixing (FWM) experiment in the mid-infrared spectral range, involving the Landau levels LL -1 , LL 0 and LL 1 . A rapid dephasing of the optically induced microscopic polarization on a time scale shorter than the pulse duration (∼4 ps) is observed, while a complementary pump-probe experiment under the same experimental conditions reveals a much longer lifetime of the induced population. The FWM signal shows the expected field dependence with respect to lowest order perturbation theory for low fields. Saturation sets in for fields above ∼6 kV/cm. Furthermore, the resonant behavior and the order of magnitude of the third-order susceptibility are in agreement with our theoretical calculations.
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