4.6 Article

A gate- and flux-controlled supercurrent diode effect

Journal

APPLIED PHYSICS LETTERS
Volume 122, Issue 4, Pages -

Publisher

AIP Publishing
DOI: 10.1063/5.0136709

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We have designed and fabricated a monolithic device that demonstrates a valuable non-reciprocal charge transport effect by utilizing a Dayem bridge-based superconducting quantum interference device. Our structure achieves rectification efficiencies (eta) up to similar to 6%. Furthermore, the absolute value and the polarity of g can be selectively modulated by an external magnetic flux or a gate voltage, offering high versatility and improved switching speed. In addition, our device operates in a wide temperature range, up to about 70% of the superconducting critical temperature of the titanium film. Our non-reciprocal charge transport effect holds great potential for extended applications in superconducting electronics, synergizing with widespread superconducting technologies such as nanocryotrons, rapid single flux quanta, and memories.
Non-reciprocal charge transport in supercurrent diodes (SDs) has polarized growing interest in the last few years for their potential applications in superconducting electronics (SCE). So far, SD effects have been reported in complex hybrid superconductor/semiconductor structures or metallic systems subject to moderate magnetic fields, thus showing limited potentiality for practical applications in SCE. Here, we report the design and realization of a monolithic device that shows a valuable SD effect by exploiting a Dayem bridge-based superconducting quantum interference device. Our structure allows reaching rectification efficiencies (eta) up to similar to 6%. Moreover, the absolute value and the polarity of g can be selected on demand by the modulation of an external magnetic flux or by a gate voltage, thereby guaranteeing high versatility and improved switching speed. Furthermore, our SD operates in a wide range of temperatures up to about 70% of the superconducting critical temperature of the titanium film composing the interferometer. Our SD effect can find extended applications in SCE by operating in synergy with widespread superconducting technologies such as nanocryotrons, rapid single flux quanta, and memories.

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