Atypical Josephson effect in hybrid superconductor-hole systems

Peter D. Johannsen; Henry F. Legg; Stefano Bosco; Daniel Loss; Jelena Klinovaja

doi:10.1103/dqgc-8crs

Atypical Josephson effect in hybrid superconductor-hole systems

Peter D. Johannsen^*, Henry F. Legg, Stefano Bosco, Daniel Loss, Jelena Klinovaja

^*Corresponding author for this work

School of Physics and Astronomy

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

Abstract

We consider hybrid systems consisting of a hole-doped semiconductor coupled to electronic states of finite-size superconductors, where the opposite sign of the masses in the two subsystems gives rise to insulating gaps at subband anticrossings. Consequently, increasing the coupling strength to the superconductor can paradoxically suppress the proximity-induced superconductivity in the semiconductor by enhancing these insulating gaps. We demonstrate that the presence of such induced insulating gaps leads to a characteristic atypical behavior of the critical supercurrent in Josephson junctions based on these hybrid structures. Our findings provide important insights for the design of robust quantum computing platforms utilizing hybrid superconductor-hole systems.

Original language	English
Article number	013289
Number of pages	18
Journal	Physical Review Research
Volume	8
Issue number	1
DOIs	https://doi.org/10.1103/dqgc-8crs
Publication status	Published - 17 Mar 2026

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Data for "Atypical Josephson effect in hybrid superconductor-hole systems"
Legg, H. (Creator), Zenodo, 2026
DOI: 10.5281/zenodo.18409848
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abstract = "We consider hybrid systems consisting of a hole-doped semiconductor coupled to electronic states of finite-size superconductors, where the opposite sign of the masses in the two subsystems gives rise to insulating gaps at subband anticrossings. Consequently, increasing the coupling strength to the superconductor can paradoxically suppress the proximity-induced superconductivity in the semiconductor by enhancing these insulating gaps. We demonstrate that the presence of such induced insulating gaps leads to a characteristic atypical behavior of the critical supercurrent in Josephson junctions based on these hybrid structures. Our findings provide important insights for the design of robust quantum computing platforms utilizing hybrid superconductor-hole systems.",

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AU - Johannsen, Peter D.

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AU - Bosco, Stefano

AU - Loss, Daniel

AU - Klinovaja, Jelena

N1 - Funding: This work was supported by the Swiss National Science Foundation (SNSF) and NCCR SPIN (Grants No. 51NF40-180604 and No. 51NF40-225153).

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N2 - We consider hybrid systems consisting of a hole-doped semiconductor coupled to electronic states of finite-size superconductors, where the opposite sign of the masses in the two subsystems gives rise to insulating gaps at subband anticrossings. Consequently, increasing the coupling strength to the superconductor can paradoxically suppress the proximity-induced superconductivity in the semiconductor by enhancing these insulating gaps. We demonstrate that the presence of such induced insulating gaps leads to a characteristic atypical behavior of the critical supercurrent in Josephson junctions based on these hybrid structures. Our findings provide important insights for the design of robust quantum computing platforms utilizing hybrid superconductor-hole systems.

AB - We consider hybrid systems consisting of a hole-doped semiconductor coupled to electronic states of finite-size superconductors, where the opposite sign of the masses in the two subsystems gives rise to insulating gaps at subband anticrossings. Consequently, increasing the coupling strength to the superconductor can paradoxically suppress the proximity-induced superconductivity in the semiconductor by enhancing these insulating gaps. We demonstrate that the presence of such induced insulating gaps leads to a characteristic atypical behavior of the critical supercurrent in Josephson junctions based on these hybrid structures. Our findings provide important insights for the design of robust quantum computing platforms utilizing hybrid superconductor-hole systems.

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Atypical Josephson effect in hybrid superconductor-hole systems

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