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Paper detail

Pump-induced terahertz anisotropy in bilayer graphene

We investigate the intraband nonlinear dynamics in doped bilayer graphene in the presence of strong, linearly-polarized, in-plane terahertz fields. We perform degenerate pump-probe experiments with 3.4 THz fields on doped bilayer graphene at low temperature (12 K) and find that when the pump is co-polarized with the probe beam, the differential pump-probe signal is almost double that found in the cross-polarized case. We show that the origin of this pump-induced anisotropy is the difference in the average electron effective mass in the probe direction when carriers are displaced in k-space by the pump either parallel or perpendicular to the direction of the probe polarization. We model the system using both a simple semiclassical model and a Boltzmann equation simulation of the electron dynamics with phenomenological scattering and find good qualitative agreement with experimental results.

preprint2022arXivOpen access
Angelika SeidlRoozbeh AnvariMarc M. DignamPeter RichterThomas SeyllerHarald SchneiderManfred HelmStephan Winnerl
cond-mat.mes-hallphysics.optics
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Angelika SeidlRoozbeh AnvariMarc M. DignamPeter RichterThomas SeyllerHarald SchneiderManfred HelmStephan Winnerl

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