Fast characterization of multiplexed single-electron pumps with machine learning

N. Schoinas; Y. Rath; S. Norimoto; W. Xie; P. See; J.P. Griffiths; C. Chen; D.A. Ritchie; M. Kataoka; Alessandro Rossi; I. Rungger

doi:10.48550/arXiv.2405.20946

Fast characterization of multiplexed single-electron pumps with machine learning

N. Schoinas, Y. Rath, S. Norimoto, W. Xie, P. See, J.P. Griffiths, C. Chen, D.A. Ritchie, M. Kataoka, Alessandro Rossi, I. Rungger

Physics

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Abstract

We present an efficient machine learning based automated framework for the fast tuning of single-electron pump devices into current quantization regimes. It uses a sparse measurement approach based on an iterative active learning algorithm to take targeted measurements in the gate voltage parameter space. When compared to conventional parameter scans, our automated framework allows us to decrease the number of measurement points by about an order of magnitude. This corresponds to an eight-fold decrease in the time required to determine quantization errors, which are estimated via an exponential extrapolation of the first current plateau embedded into the algorithm. We show the robustness of the framework by characterizing 28 individual devices arranged in a GaAs/AlGaAs multiplexer array, which we use to identify a subset of devices suitable for parallel operation at communal gate voltages. The method opens up the possibility to efficiently scale the characterization of such multiplexed devices to a large number of pumps.

Original language	English
Place of Publication	Ithaca, NY
Number of pages	6
DOIs	https://doi.org/10.48550/arXiv.2405.20946
Publication status	Published - 31 May 2024

Funding

The authors acknowledge the support of the Innovate UK project AutoQT (grant number 1004359), and of the UK government Department for Science, Innovation and Technology through the UK National Quantum Technologies Programme. A.R. acknowledges support from a UKRI Future Leaders Fellowship (MR/T041110/1).

Keywords

machine learning algorithms
quantum dot arrays
single-electron pump
ampere
quantum electrical metrology

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Schoinas-etal-arXiv-2024-Fast-characterization-of-multiplexed-single-electron-pumpsFinal published version, 850 KBLicence: CC BY 4.0
2405.20946v1

1 Article

Fast characterization of multiplexed single-electron pumps with machine learning
Schoinas, N., Rath, Y., Norimoto, S., Xie, W., See, P., Griffiths, J. P., Chen, C., Ritchie, D. A., Kataoka, M., Rossi, A. & Rungger, I., 16 Sept 2024, In: Applied Physics Letters. 125, 12, 124001.
Research output: Contribution to journal › Article › peer-review

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Cite this

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abstract = "We present an efficient machine learning based automated framework for the fast tuning of single-electron pump devices into current quantization regimes. It uses a sparse measurement approach based on an iterative active learning algorithm to take targeted measurements in the gate voltage parameter space. When compared to conventional parameter scans, our automated framework allows us to decrease the number of measurement points by about an order of magnitude. This corresponds to an eight-fold decrease in the time required to determine quantization errors, which are estimated via an exponential extrapolation of the first current plateau embedded into the algorithm. We show the robustness of the framework by characterizing 28 individual devices arranged in a GaAs/AlGaAs multiplexer array, which we use to identify a subset of devices suitable for parallel operation at communal gate voltages. The method opens up the possibility to efficiently scale the characterization of such multiplexed devices to a large number of pumps.",

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author = "N. Schoinas and Y. Rath and S. Norimoto and W. Xie and P. See and J.P. Griffiths and C. Chen and D.A. Ritchie and M. Kataoka and Alessandro Rossi and I. Rungger",

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AU - Xie, W.

AU - See, P.

AU - Griffiths, J.P.

AU - Chen, C.

AU - Ritchie, D.A.

AU - Kataoka, M.

AU - Rossi, Alessandro

AU - Rungger, I.

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N2 - We present an efficient machine learning based automated framework for the fast tuning of single-electron pump devices into current quantization regimes. It uses a sparse measurement approach based on an iterative active learning algorithm to take targeted measurements in the gate voltage parameter space. When compared to conventional parameter scans, our automated framework allows us to decrease the number of measurement points by about an order of magnitude. This corresponds to an eight-fold decrease in the time required to determine quantization errors, which are estimated via an exponential extrapolation of the first current plateau embedded into the algorithm. We show the robustness of the framework by characterizing 28 individual devices arranged in a GaAs/AlGaAs multiplexer array, which we use to identify a subset of devices suitable for parallel operation at communal gate voltages. The method opens up the possibility to efficiently scale the characterization of such multiplexed devices to a large number of pumps.

AB - We present an efficient machine learning based automated framework for the fast tuning of single-electron pump devices into current quantization regimes. It uses a sparse measurement approach based on an iterative active learning algorithm to take targeted measurements in the gate voltage parameter space. When compared to conventional parameter scans, our automated framework allows us to decrease the number of measurement points by about an order of magnitude. This corresponds to an eight-fold decrease in the time required to determine quantization errors, which are estimated via an exponential extrapolation of the first current plateau embedded into the algorithm. We show the robustness of the framework by characterizing 28 individual devices arranged in a GaAs/AlGaAs multiplexer array, which we use to identify a subset of devices suitable for parallel operation at communal gate voltages. The method opens up the possibility to efficiently scale the characterization of such multiplexed devices to a large number of pumps.

KW - machine learning algorithms

KW - quantum dot arrays

KW - single-electron pump

KW - ampere

KW - quantum electrical metrology

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BT - Fast characterization of multiplexed single-electron pumps with machine learning

CY - Ithaca, NY

ER -

Fast characterization of multiplexed single-electron pumps with machine learning

Abstract

Funding

Keywords

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Research output

Fast characterization of multiplexed single-electron pumps with machine learning

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