Optical recombination of biexcitons in semiconductors

M. Bauer; Jonathan Mark James Keeling; M. M. Parish; P. Lopez Rios; P. B. Littlewood

doi:10.1103/PhysRevB.87.035302

Optical recombination of biexcitons in semiconductors

M. Bauer, Jonathan Mark James Keeling, M. M. Parish, P. Lopez Rios, P. B. Littlewood

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

Abstract

We calculate the photoluminescence spectrum and lifetime of a biexciton in a semiconductor using Fermi's golden rule. Our biexciton wavefunction is obtained using a Quantum Monte Carlo calculation. We consider a recombination process where one of the excitons within the biexciton annihilates. For hole masses greater than or equal to the electron mass, we find that the surviving exciton is most likely to populate the ground state. We also investigate how the confinement of excitons in a quantum dot would modify the lifetime in the limit of a large quantum dot where confinement principally affects the centre of mass wavefunction. The lifetimes we obtain are in reasonable agreement with experimental values. Our calculation can be used as a benchmark for comparison with approximate methods.

Original language	English
Article number	035302
Journal	Physical Review. B, Condensed matter and materials physics
Volume	87
Issue number	3
DOIs	https://doi.org/10.1103/PhysRevB.87.035302
Publication status	Published - 7 Jan 2013

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Macroscopic quantum coherence: Macroscopic quantum coherence in non-equilibrium and driven quantum systems
Keeling, J. M. J. (PI)
EPSRC
1/09/10 → 31/03/14
Project: Fellowship

Cite this

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title = "Optical recombination of biexcitons in semiconductors",

abstract = "We calculate the photoluminescence spectrum and lifetime of a biexciton in a semiconductor using Fermi's golden rule. Our biexciton wavefunction is obtained using a Quantum Monte Carlo calculation. We consider a recombination process where one of the excitons within the biexciton annihilates. For hole masses greater than or equal to the electron mass, we find that the surviving exciton is most likely to populate the ground state. We also investigate how the confinement of excitons in a quantum dot would modify the lifetime in the limit of a large quantum dot where confinement principally affects the centre of mass wavefunction. The lifetimes we obtain are in reasonable agreement with experimental values. Our calculation can be used as a benchmark for comparison with approximate methods.",

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AU - Bauer, M.

AU - Keeling, Jonathan Mark James

AU - Parish, M. M.

AU - Lopez Rios, P.

AU - Littlewood, P. B.

N1 - 6 pages, 2 figures

PY - 2013/1/7

Y1 - 2013/1/7

N2 - We calculate the photoluminescence spectrum and lifetime of a biexciton in a semiconductor using Fermi's golden rule. Our biexciton wavefunction is obtained using a Quantum Monte Carlo calculation. We consider a recombination process where one of the excitons within the biexciton annihilates. For hole masses greater than or equal to the electron mass, we find that the surviving exciton is most likely to populate the ground state. We also investigate how the confinement of excitons in a quantum dot would modify the lifetime in the limit of a large quantum dot where confinement principally affects the centre of mass wavefunction. The lifetimes we obtain are in reasonable agreement with experimental values. Our calculation can be used as a benchmark for comparison with approximate methods.

AB - We calculate the photoluminescence spectrum and lifetime of a biexciton in a semiconductor using Fermi's golden rule. Our biexciton wavefunction is obtained using a Quantum Monte Carlo calculation. We consider a recombination process where one of the excitons within the biexciton annihilates. For hole masses greater than or equal to the electron mass, we find that the surviving exciton is most likely to populate the ground state. We also investigate how the confinement of excitons in a quantum dot would modify the lifetime in the limit of a large quantum dot where confinement principally affects the centre of mass wavefunction. The lifetimes we obtain are in reasonable agreement with experimental values. Our calculation can be used as a benchmark for comparison with approximate methods.

U2 - 10.1103/PhysRevB.87.035302

DO - 10.1103/PhysRevB.87.035302

M3 - Article

SN - 1098-0121

VL - 87

JO - Physical Review. B, Condensed matter and materials physics

JF - Physical Review. B, Condensed matter and materials physics

IS - 3

M1 - 035302

ER -

Optical recombination of biexcitons in semiconductors

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Macroscopic quantum coherence: Macroscopic quantum coherence in non-equilibrium and driven quantum systems

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