Bridging the Reality Gap in Quantum Devices with Physics-Aware Machine Learning

D. L. Craig; H. Moon; F. Fedele; D. T. Lennon; B. van Straaten; F. Vigneau; L. C. Camenzind; D. M. Zumbühl; G. A. D. Briggs; M. A. Osborne; D. Sejdinovic; N. Ares

doi:10.1103/PhysRevX.14.011001

Physical Review X (Jan 2024)

Bridging the Reality Gap in Quantum Devices with Physics-Aware Machine Learning

D. L. Craig,
H. Moon,
F. Fedele,
D. T. Lennon,
B. van Straaten,
F. Vigneau,
L. C. Camenzind,
D. M. Zumbühl,
G. A. D. Briggs,
M. A. Osborne,
D. Sejdinovic,
N. Ares

Affiliations

D. L. Craig
H. Moon
F. Fedele
D. T. Lennon
B. van Straaten
F. Vigneau
L. C. Camenzind
D. M. Zumbühl
G. A. D. Briggs
M. A. Osborne
D. Sejdinovic
N. Ares

DOI: https://doi.org/10.1103/PhysRevX.14.011001
Journal volume & issue: Vol. 14, no. 1
p. 011001

Abstract

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The discrepancies between reality and simulation impede the optimization and scalability of solid-state quantum devices. Disorder induced by the unpredictable distribution of material defects is one of the major contributions to the reality gap. We bridge this gap using physics-aware machine learning, in particular, using an approach combining a physical model, deep learning, Gaussian random field, and Bayesian inference. This approach enables us to infer the disorder potential of a nanoscale electronic device from electron-transport data. This inference is validated by verifying the algorithm’s predictions about the gate-voltage values required for a laterally defined quantum-dot device in AlGaAs/GaAs to produce current features corresponding to a double-quantum-dot regime.

Published in Physical Review X

ISSN: 2160-3308 (Online)
Publisher: American Physical Society
Country of publisher: United States
LCC subjects: Science: Physics
Website: https://journals.aps.org/prx/

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