Strong electron spin-Hall effect by a coherent optical potential

E. Ya Sherman; J. G. Muga; V. K. Dugaev; A. Ruschhaupt

doi:10.1088/0268-1242/25/9/095004

Strong electron spin-Hall effect by a coherent optical potential

E. Ya Sherman
, J. G. Muga
, V. K. Dugaev
, A. Ruschhaupt

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

Abstract

We demonstrate theoretically that a coherent manipulation of electron spins in low-dimensional semiconductor structures with a spin-orbit coupling by infrared radiation is possible. The proposed approach is based on using a dipole force acting on a two-level system in a nonuniform optical field, similar to that employed in the design of the cold atoms diode. For ballistic electrons the spin-dependent force, proportional to the intensity of external radiation, leads to a spin-Hall effect and the resulting spin separation even if the spin-orbit coupling itself does not allow for these effects. Achievable spatial separation of electrons with opposite spins can be of the order of several tenths of a micron; an order of magnitude larger than that can be produced by the charged impurity scattering in the diffusive regime.

Original language	English
Article number	095004
Journal	Semiconductor Science and Technology
Volume	25
Issue number	9
DOIs	https://doi.org/10.1088/0268-1242/25/9/095004
Publication status	Published - Sep 2010
Externally published	Yes

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title = "Strong electron spin-Hall effect by a coherent optical potential",

abstract = "We demonstrate theoretically that a coherent manipulation of electron spins in low-dimensional semiconductor structures with a spin-orbit coupling by infrared radiation is possible. The proposed approach is based on using a dipole force acting on a two-level system in a nonuniform optical field, similar to that employed in the design of the cold atoms diode. For ballistic electrons the spin-dependent force, proportional to the intensity of external radiation, leads to a spin-Hall effect and the resulting spin separation even if the spin-orbit coupling itself does not allow for these effects. Achievable spatial separation of electrons with opposite spins can be of the order of several tenths of a micron; an order of magnitude larger than that can be produced by the charged impurity scattering in the diffusive regime.",

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AU - Sherman, E. Ya

AU - Muga, J. G.

AU - Dugaev, V. K.

AU - Ruschhaupt, A.

PY - 2010/9

Y1 - 2010/9

N2 - We demonstrate theoretically that a coherent manipulation of electron spins in low-dimensional semiconductor structures with a spin-orbit coupling by infrared radiation is possible. The proposed approach is based on using a dipole force acting on a two-level system in a nonuniform optical field, similar to that employed in the design of the cold atoms diode. For ballistic electrons the spin-dependent force, proportional to the intensity of external radiation, leads to a spin-Hall effect and the resulting spin separation even if the spin-orbit coupling itself does not allow for these effects. Achievable spatial separation of electrons with opposite spins can be of the order of several tenths of a micron; an order of magnitude larger than that can be produced by the charged impurity scattering in the diffusive regime.

AB - We demonstrate theoretically that a coherent manipulation of electron spins in low-dimensional semiconductor structures with a spin-orbit coupling by infrared radiation is possible. The proposed approach is based on using a dipole force acting on a two-level system in a nonuniform optical field, similar to that employed in the design of the cold atoms diode. For ballistic electrons the spin-dependent force, proportional to the intensity of external radiation, leads to a spin-Hall effect and the resulting spin separation even if the spin-orbit coupling itself does not allow for these effects. Achievable spatial separation of electrons with opposite spins can be of the order of several tenths of a micron; an order of magnitude larger than that can be produced by the charged impurity scattering in the diffusive regime.

UR - https://www.scopus.com/pages/publications/78649357049

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DO - 10.1088/0268-1242/25/9/095004

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VL - 25

JO - Semiconductor Science and Technology

JF - Semiconductor Science and Technology

IS - 9

M1 - 095004

ER -

Strong electron spin-Hall effect by a coherent optical potential

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