Controlling the error mechanism in a tunable-barrier nonadiabatic charge pump by dynamic gate compensation

Research output: Contribution to journalArticleResearchpeer review

Authors

  • Frank Hohls
  • Vyacheslavs Kashcheyevs
  • Friederike Stein
  • Tobias Wenz
  • Bernd Kaestner
  • Hans W. Schumacher

External Research Organisations

  • Physikalisch-Technische Bundesanstalt PTB
  • University of Latvia
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Details

Original languageEnglish
Article number205425
JournalPhysical Review B
Volume105
Issue number20
Publication statusPublished - 20 May 2022
Externally publishedYes

Abstract

Single-electron pumps based on tunable-barrier quantum dots are the most promising candidates for a direct realization of the unit ampere in the recently revised International System of Units (SI): they are simple to operate and show high precision at high operation frequencies. The current understanding of the residual transfer errors at low temperature is based on the evaluation of back-tunneling effects in the decay cascade model. This model predicts a strong dependence on the ratio of the time-dependent changes in the quantum dot energy and the tunneling barrier transparency. Here we employ a two-gate operation scheme to verify this prediction and demonstrate control of the back-tunneling error. We derive and experimentally verify a quantitative prediction for the error suppression, thereby confirming the basic assumptions of the back-tunneling (decay cascade) model. Furthermore, we demonstrate a controlled transition from the back-tunneling dominated regime into the thermal (sudden decoupling) error regime. The suppression of transfer errors by several orders of magnitude at zero magnetic field was additionally verified by a sub-ppm precision measurement.

ASJC Scopus subject areas

Cite this

Controlling the error mechanism in a tunable-barrier nonadiabatic charge pump by dynamic gate compensation. / Hohls, Frank; Kashcheyevs, Vyacheslavs; Stein, Friederike et al.
In: Physical Review B, Vol. 105, No. 20, 205425, 20.05.2022.

Research output: Contribution to journalArticleResearchpeer review

Hohls, F, Kashcheyevs, V, Stein, F, Wenz, T, Kaestner, B & Schumacher, HW 2022, 'Controlling the error mechanism in a tunable-barrier nonadiabatic charge pump by dynamic gate compensation', Physical Review B, vol. 105, no. 20, 205425. https://doi.org/10.1103/PhysRevB.105.205425
Hohls, F., Kashcheyevs, V., Stein, F., Wenz, T., Kaestner, B., & Schumacher, H. W. (2022). Controlling the error mechanism in a tunable-barrier nonadiabatic charge pump by dynamic gate compensation. Physical Review B, 105(20), Article 205425. https://doi.org/10.1103/PhysRevB.105.205425
Hohls F, Kashcheyevs V, Stein F, Wenz T, Kaestner B, Schumacher HW. Controlling the error mechanism in a tunable-barrier nonadiabatic charge pump by dynamic gate compensation. Physical Review B. 2022 May 20;105(20):205425. doi: 10.1103/PhysRevB.105.205425
Hohls, Frank ; Kashcheyevs, Vyacheslavs ; Stein, Friederike et al. / Controlling the error mechanism in a tunable-barrier nonadiabatic charge pump by dynamic gate compensation. In: Physical Review B. 2022 ; Vol. 105, No. 20.
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abstract = "Single-electron pumps based on tunable-barrier quantum dots are the most promising candidates for a direct realization of the unit ampere in the recently revised International System of Units (SI): they are simple to operate and show high precision at high operation frequencies. The current understanding of the residual transfer errors at low temperature is based on the evaluation of back-tunneling effects in the decay cascade model. This model predicts a strong dependence on the ratio of the time-dependent changes in the quantum dot energy and the tunneling barrier transparency. Here we employ a two-gate operation scheme to verify this prediction and demonstrate control of the back-tunneling error. We derive and experimentally verify a quantitative prediction for the error suppression, thereby confirming the basic assumptions of the back-tunneling (decay cascade) model. Furthermore, we demonstrate a controlled transition from the back-tunneling dominated regime into the thermal (sudden decoupling) error regime. The suppression of transfer errors by several orders of magnitude at zero magnetic field was additionally verified by a sub-ppm precision measurement.",
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