M. V. Entin

Theory of resonant photon drag in monolayer graphene

Photon drag current in monolayer graphene with degenerate electron gas is studied under interband excitation near the threshold of fundamental transitions. Two main mechanisms generate an emergence of electron current. Non-resonant drag effect (NDE) results from direct transfer of in-plane photon momentum

Photogalvanic current in artificial asymmetric nanostructures

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Conductivity of 2D multi-component electron gas partially-quantized by magnetic field

to electron and dependence of matrix elements of transitions on

Coherent photogalvanic valley Hall effect

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Edge states on the curved boundary of a 2D topological insulator

. Resonant drag effect (RDE) originates from

Edge excitons in a 2D topological insulator in a magnetic field

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Is the Edge States Energy Spectrum of a 2D Topological Insulator Linear

-dependent selection of transitions due to a sharp form of the Fermi distribution in energy. The drag current essentially depends on the polarization of radiation and, in general, is not parallel to

Linearity of the edge states energy spectrum in the 2D topological insulator

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Ratchet transport of interacting particles

. The perpendicular current component appears if the in-plain electric field is tilted towards

Theory of photogalvanic effect in asymmetric nanostructure arrays

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