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Exciton-polariton interference controlled by electric field. / Логинов, Дмитрий Константинович; Белов, Павел Алексеевич; Давыдов, Валентин Геннадьевич; Герловин, Илья Яковлевич; Игнатьев, Иван Владимирович; Кавокин, Алексей Витальевич; Masumoto, Y.

в: Physical Review Research, Том 2, 033510, 2020.

Результаты исследований: Научные публикации в периодических изданияхстатьяРецензирование

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@article{6577c892c21c43f282c06ca705003ac5,
title = "Exciton-polariton interference controlled by electric field",
abstract = "Linear-in-wave-vector K terms of an electron Hamiltonian play an important role in topological insulators and spintronic devices. Here we demonstrate how an external electric field can control the magnitude of a linear-in-K term in the exciton Hamiltonian. The effect of the electric field on interference of exciton polaritons in a high-quality structure with a wide GaAs quantum well was experimentally studied by means of the differential reflection spectroscopy. It is found that the interference pattern is strongly suppressed at certain electric field and then it is reinstalled, but with an inverted phase, at the further increase of the field. This behavior of the pattern is successfully explained by the electric-field-induced linear-in-K terms in the Hamiltonian of the exciton propagating across the quantum well. An excellent agreement between the experimental data and the results of calculations using semiclassical nonlocal dielectric response model confirms the validity of the method and paves the way for the realization of excitonic Datta-Das transistors. In full analogy with the spin-orbit transistor proposed by Datta and Das [Appl. Phys. Lett. 56, 665 (1990)], the switch between positive and negative interference of exciton polaritons propagating forward and backward in a GaAs film is achieved by application of an electric field having a nonzero component in the plane of the quantum well layer.",
keywords = "Dielectric properties, EXCITON POLARITONS, Exciton, Permittivity, Dielectric properties, Exciton polariton, Exciton, Permittivity",
author = "Логинов, {Дмитрий Константинович} and Белов, {Павел Алексеевич} and Давыдов, {Валентин Геннадьевич} and Герловин, {Илья Яковлевич} and Игнатьев, {Иван Владимирович} and Кавокин, {Алексей Витальевич} and Y. Masumoto",
year = "2020",
doi = "10.1103/PhysRevResearch.2.033510",
language = "English",
volume = "2",
journal = "Physical Review Research",
issn = "2643-1564",
publisher = "American Physical Society",

}

RIS

TY - JOUR

T1 - Exciton-polariton interference controlled by electric field

AU - Логинов, Дмитрий Константинович

AU - Белов, Павел Алексеевич

AU - Давыдов, Валентин Геннадьевич

AU - Герловин, Илья Яковлевич

AU - Игнатьев, Иван Владимирович

AU - Кавокин, Алексей Витальевич

AU - Masumoto, Y.

PY - 2020

Y1 - 2020

N2 - Linear-in-wave-vector K terms of an electron Hamiltonian play an important role in topological insulators and spintronic devices. Here we demonstrate how an external electric field can control the magnitude of a linear-in-K term in the exciton Hamiltonian. The effect of the electric field on interference of exciton polaritons in a high-quality structure with a wide GaAs quantum well was experimentally studied by means of the differential reflection spectroscopy. It is found that the interference pattern is strongly suppressed at certain electric field and then it is reinstalled, but with an inverted phase, at the further increase of the field. This behavior of the pattern is successfully explained by the electric-field-induced linear-in-K terms in the Hamiltonian of the exciton propagating across the quantum well. An excellent agreement between the experimental data and the results of calculations using semiclassical nonlocal dielectric response model confirms the validity of the method and paves the way for the realization of excitonic Datta-Das transistors. In full analogy with the spin-orbit transistor proposed by Datta and Das [Appl. Phys. Lett. 56, 665 (1990)], the switch between positive and negative interference of exciton polaritons propagating forward and backward in a GaAs film is achieved by application of an electric field having a nonzero component in the plane of the quantum well layer.

AB - Linear-in-wave-vector K terms of an electron Hamiltonian play an important role in topological insulators and spintronic devices. Here we demonstrate how an external electric field can control the magnitude of a linear-in-K term in the exciton Hamiltonian. The effect of the electric field on interference of exciton polaritons in a high-quality structure with a wide GaAs quantum well was experimentally studied by means of the differential reflection spectroscopy. It is found that the interference pattern is strongly suppressed at certain electric field and then it is reinstalled, but with an inverted phase, at the further increase of the field. This behavior of the pattern is successfully explained by the electric-field-induced linear-in-K terms in the Hamiltonian of the exciton propagating across the quantum well. An excellent agreement between the experimental data and the results of calculations using semiclassical nonlocal dielectric response model confirms the validity of the method and paves the way for the realization of excitonic Datta-Das transistors. In full analogy with the spin-orbit transistor proposed by Datta and Das [Appl. Phys. Lett. 56, 665 (1990)], the switch between positive and negative interference of exciton polaritons propagating forward and backward in a GaAs film is achieved by application of an electric field having a nonzero component in the plane of the quantum well layer.

KW - Dielectric properties

KW - EXCITON POLARITONS

KW - Exciton

KW - Permittivity

KW - Dielectric properties

KW - Exciton polariton

KW - Exciton

KW - Permittivity

UR - https://www.mendeley.com/catalogue/93523838-254b-37b1-b5f9-5bd11c1e93b1/

U2 - 10.1103/PhysRevResearch.2.033510

DO - 10.1103/PhysRevResearch.2.033510

M3 - Article

VL - 2

JO - Physical Review Research

JF - Physical Review Research

SN - 2643-1564

M1 - 033510

ER -

ID: 62790832