Eliminating the confined dark-exciton qubit precession using an externally applied magnetic field

Zu En Su; Dan Cogan; Ido Schwartz; Ayal Beck; David Gershoni

doi:10.1103/PhysRevB.111.L161302

Eliminating the confined dark-exciton qubit precession using an externally applied magnetic field

Zu En Su, Dan Cogan, Ido Schwartz, Ayal Beck, David Gershoni

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

Abstract

We investigate experimentally and theoretically the behavior of the confined dark exciton in an InAs/GaAs semiconductor quantum dot, under the application of an external magnetic field in a Voigt configuration. We show that by varying the magnitude and direction of the external field one can accurately control the dark-exciton fine-structure splitting. In addition, we show that the dark-exciton spin state is approximately polarized along the cubic crystallographic directions [100] or equivalents. By comparing our experimental results with a model for the exchange and Zeeman interactions, we find the conditions for nullifying the fine-structure splitting between the two eigenstates of the dark exciton, thereby stopping its qubit precession.

Original language	English
Article number	L161302
Journal	Physical Review B
Volume	111
Issue number	16
DOIs	https://doi.org/10.1103/PhysRevB.111.L161302
State	Published - 15 Apr 2025

ASJC Scopus subject areas

Electronic, Optical and Magnetic Materials
Condensed Matter Physics

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10.1103/PhysRevB.111.L161302

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title = "Eliminating the confined dark-exciton qubit precession using an externally applied magnetic field",

abstract = "We investigate experimentally and theoretically the behavior of the confined dark exciton in an InAs/GaAs semiconductor quantum dot, under the application of an external magnetic field in a Voigt configuration. We show that by varying the magnitude and direction of the external field one can accurately control the dark-exciton fine-structure splitting. In addition, we show that the dark-exciton spin state is approximately polarized along the cubic crystallographic directions [100] or equivalents. By comparing our experimental results with a model for the exchange and Zeeman interactions, we find the conditions for nullifying the fine-structure splitting between the two eigenstates of the dark exciton, thereby stopping its qubit precession.",

author = "Su, \{Zu En\} and Dan Cogan and Ido Schwartz and Ayal Beck and David Gershoni",

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AU - Cogan, Dan

AU - Schwartz, Ido

AU - Beck, Ayal

AU - Gershoni, David

PY - 2025/4/15

Y1 - 2025/4/15

N2 - We investigate experimentally and theoretically the behavior of the confined dark exciton in an InAs/GaAs semiconductor quantum dot, under the application of an external magnetic field in a Voigt configuration. We show that by varying the magnitude and direction of the external field one can accurately control the dark-exciton fine-structure splitting. In addition, we show that the dark-exciton spin state is approximately polarized along the cubic crystallographic directions [100] or equivalents. By comparing our experimental results with a model for the exchange and Zeeman interactions, we find the conditions for nullifying the fine-structure splitting between the two eigenstates of the dark exciton, thereby stopping its qubit precession.

AB - We investigate experimentally and theoretically the behavior of the confined dark exciton in an InAs/GaAs semiconductor quantum dot, under the application of an external magnetic field in a Voigt configuration. We show that by varying the magnitude and direction of the external field one can accurately control the dark-exciton fine-structure splitting. In addition, we show that the dark-exciton spin state is approximately polarized along the cubic crystallographic directions [100] or equivalents. By comparing our experimental results with a model for the exchange and Zeeman interactions, we find the conditions for nullifying the fine-structure splitting between the two eigenstates of the dark exciton, thereby stopping its qubit precession.

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JO - Physical Review B

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Eliminating the confined dark-exciton qubit precession using an externally applied magnetic field

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