Optical Ionization of Qubits and their Silent Charge States

Michel Bockstedte; Maximilian Schober

doi:10.4028/p-9trMUe

Optical Ionization of Qubits and their Silent Charge States

Michel Bockstedte, Maximilian Schober

Department of Many Particle Systems

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

Abstract

Color centers in the technologically mature material silicon carbide are candidates for the implementation of quantum applications. Chargestate control and electrical read-out of qubits includes spin-to-charge conversion via optical excitation and subsequent ionization. In this work we address the dominant photoionization mechanism and the photophysical properties of the ionized silicon vacancy in 4H SiC using ab initio theory. We find that its nominally dark chargestates are infrared emitters.

Original language	English
Pages (from-to)	9-15
Number of pages	7
Journal	Key Engineering Materials
Volume	984
DOIs	https://doi.org/10.4028/p-9trMUe
Publication status	Published - Aug 2024

Fields of science

103 Physics, Astronomy

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10.4028/p-9trMUe

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title = "Optical Ionization of Qubits and their Silent Charge States",

abstract = "Color centers in the technologically mature material silicon carbide are candidates for the implementation of quantum applications. Chargestate control and electrical read-out of qubits includes spin-to-charge conversion via optical excitation and subsequent ionization. In this work we address the dominant photoionization mechanism and the photophysical properties of the ionized silicon vacancy in 4H SiC using ab initio theory. We find that its nominally dark chargestates are infrared emitters.",

author = "Michel Bockstedte and Maximilian Schober",

year = "2024",

month = aug,

doi = "10.4028/p-9trMUe",

language = "English",

volume = "984",

pages = "9--15",

journal = "Key Engineering Materials",

issn = "1662-9795",

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T1 - Optical Ionization of Qubits and their Silent Charge States

AU - Bockstedte, Michel

AU - Schober, Maximilian

PY - 2024/8

Y1 - 2024/8

N2 - Color centers in the technologically mature material silicon carbide are candidates for the implementation of quantum applications. Chargestate control and electrical read-out of qubits includes spin-to-charge conversion via optical excitation and subsequent ionization. In this work we address the dominant photoionization mechanism and the photophysical properties of the ionized silicon vacancy in 4H SiC using ab initio theory. We find that its nominally dark chargestates are infrared emitters.

AB - Color centers in the technologically mature material silicon carbide are candidates for the implementation of quantum applications. Chargestate control and electrical read-out of qubits includes spin-to-charge conversion via optical excitation and subsequent ionization. In this work we address the dominant photoionization mechanism and the photophysical properties of the ionized silicon vacancy in 4H SiC using ab initio theory. We find that its nominally dark chargestates are infrared emitters.

UR - https://www.scopus.com/pages/publications/85204787994

U2 - 10.4028/p-9trMUe

DO - 10.4028/p-9trMUe

M3 - Article

SN - 1662-9795

VL - 984

SP - 9

EP - 15

JO - Key Engineering Materials

JF - Key Engineering Materials

ER -

Optical Ionization of Qubits and their Silent Charge States

Abstract

Fields of science

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Point Defects in SiC: Coupling of Light, Spin, and Matter

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Optical Ionization of Qubits and their Silent Charge States

Abstract

Fields of science

Access to Document

Other files and links

Projects

Point Defects in SiC: Coupling of Light, Spin, and Matter

Cite this