Dominant channels of exciton spin relaxation in photoexcited self-assembled (In,Ga)As quantum dots

Yu Huai Liao; Juan I. Climente; Shun-Jen Cheng

doi:10.1103/PhysRevB.83.165317

Dominant channels of exciton spin relaxation in photoexcited self-assembled (In,Ga)As quantum dots

Yu Huai Liao^*, Juan I. Climente, Shun-Jen Cheng

^*Corresponding author for this work

Department of Electrophysics

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

16 Scopus citations

Abstract

We present a comprehensive theoretical investigation of spin relaxation processes of excitons in photoexcited self-assembled quantum dots. The exciton spin relaxations are considered between dark- and bright-exciton states via the channels created by various spin-admixture mechanisms, including electron Rashba and Dresselhaus spin-orbital couplings (SOCs), hole linear and hole cubic SOCs, and electron hyperfine interactions, incorporated with single- and double-phonon processes. The hole-Dresselhaus SOC is identified as the dominant spin-admixture mechanism, leading to relaxation rates as fast as ∼10 ^-2 ns^-1, consistent with recent observations. Moreover, due to significant electron-hole exchange interactions, single-phonon processes are unusually dominant over two-phonon ones in a photoexcited dot even at temperatures as high as 15K.

Original language	English
Article number	165317
Journal	Physical Review B - Condensed Matter and Materials Physics
Volume	83
Issue number	16
DOIs	https://doi.org/10.1103/PhysRevB.83.165317
State	Published - 22 Apr 2011

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title = "Dominant channels of exciton spin relaxation in photoexcited self-assembled (In,Ga)As quantum dots",

abstract = "We present a comprehensive theoretical investigation of spin relaxation processes of excitons in photoexcited self-assembled quantum dots. The exciton spin relaxations are considered between dark- and bright-exciton states via the channels created by various spin-admixture mechanisms, including electron Rashba and Dresselhaus spin-orbital couplings (SOCs), hole linear and hole cubic SOCs, and electron hyperfine interactions, incorporated with single- and double-phonon processes. The hole-Dresselhaus SOC is identified as the dominant spin-admixture mechanism, leading to relaxation rates as fast as ∼10 -2 ns-1, consistent with recent observations. Moreover, due to significant electron-hole exchange interactions, single-phonon processes are unusually dominant over two-phonon ones in a photoexcited dot even at temperatures as high as 15K.",

author = "Liao, {Yu Huai} and Climente, {Juan I.} and Shun-Jen Cheng",

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AU - Liao, Yu Huai

AU - Climente, Juan I.

AU - Cheng, Shun-Jen

PY - 2011/4/22

Y1 - 2011/4/22

N2 - We present a comprehensive theoretical investigation of spin relaxation processes of excitons in photoexcited self-assembled quantum dots. The exciton spin relaxations are considered between dark- and bright-exciton states via the channels created by various spin-admixture mechanisms, including electron Rashba and Dresselhaus spin-orbital couplings (SOCs), hole linear and hole cubic SOCs, and electron hyperfine interactions, incorporated with single- and double-phonon processes. The hole-Dresselhaus SOC is identified as the dominant spin-admixture mechanism, leading to relaxation rates as fast as ∼10 -2 ns-1, consistent with recent observations. Moreover, due to significant electron-hole exchange interactions, single-phonon processes are unusually dominant over two-phonon ones in a photoexcited dot even at temperatures as high as 15K.

AB - We present a comprehensive theoretical investigation of spin relaxation processes of excitons in photoexcited self-assembled quantum dots. The exciton spin relaxations are considered between dark- and bright-exciton states via the channels created by various spin-admixture mechanisms, including electron Rashba and Dresselhaus spin-orbital couplings (SOCs), hole linear and hole cubic SOCs, and electron hyperfine interactions, incorporated with single- and double-phonon processes. The hole-Dresselhaus SOC is identified as the dominant spin-admixture mechanism, leading to relaxation rates as fast as ∼10 -2 ns-1, consistent with recent observations. Moreover, due to significant electron-hole exchange interactions, single-phonon processes are unusually dominant over two-phonon ones in a photoexcited dot even at temperatures as high as 15K.

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Dominant channels of exciton spin relaxation in photoexcited self-assembled (In,Ga)As quantum dots

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