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arxiv: 2406.12175 · v5 · pith:EYJSKUQB · submitted 2024-06-18 · physics.app-ph

A superconducting full-wave bridge rectifier

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classification physics.app-ph
keywords superconductingrectificationasymmetricbridgecircuitsdevicesdiodeefficiency
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Superconducting thin-film electronics are attractive for their low power consumption, fast operating speeds, and ease of interface with cryogenic systems such as single-photon detector arrays, and quantum computing devices. However, the lack of a reliable superconducting two-terminal asymmetric device, analogous to a semiconducting diode, limits the development of power-handling circuits, fundamental for scaling up these technologies. Existing efforts to date have been limited to single-diode proofs of principle and lacked integration of multiple controllable and reproducible devices to form complex circuits. Here, we demonstrate a robust superconducting diode with tunable polarity using the asymmetric vortex surface barrier in niobium nitride micro-bridges, achieving a 43% peak rectification efficiency, and showing half-wave rectification up to 120 MHz. We then realize and integrate several such diodes into a bridge rectifier circuit on a single microchip that performs continuous full-wave rectification up to 3 MHz and AC-to-DC conversion of a 50 MHz signal in periodic bursts with an estimated peak power efficiency of 50%.

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Cited by 1 Pith paper

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    Chiral cavity photon exchange induces orbital magnetization that embeds chirality into a superconductor's ground state, producing a photo-controlled diode nonreciprocity demonstrated in principle for twisted bilayer graphene.