Gate-tunable double-loop SQUID achieves superconducting diode efficiency exceeding 50 percent by independent control of three interfering current-phase relationships.
Title resolution pending
3 Pith papers cite this work. Polarity classification is still indexing.
3
Pith papers citing it
citation-role summary
background 1
citation-polarity summary
fields
cond-mat.supr-con 3roles
background 1polarities
unclear 1representative citing papers
Mo2C nanoflakes exhibit both tunable field-odd SDE exceeding 40% efficiency and robust field-free SDE, attributed to domain boundaries or CDW-like orders.
Non-Hermitian dissipation shifts 0-π transitions in magnetic Josephson junctions to higher fields and enables angle-based control at fixed magnitude via complex eigenvalues of the effective Hamiltonian.
citing papers explorer
-
High efficiency superconducting diode effect in a gate-tunable double-loop SQUID
Gate-tunable double-loop SQUID achieves superconducting diode efficiency exceeding 50 percent by independent control of three interfering current-phase relationships.
-
Observation of field-odd and field-free superconducting diode effects in $\mathrm{Mo}_2\mathrm{C}$ nanoflakes
Mo2C nanoflakes exhibit both tunable field-odd SDE exceeding 40% efficiency and robust field-free SDE, attributed to domain boundaries or CDW-like orders.
-
$0-\pi$ transitions in non-Hermitian magnetic Josephson junctions
Non-Hermitian dissipation shifts 0-π transitions in magnetic Josephson junctions to higher fields and enables angle-based control at fixed magnitude via complex eigenvalues of the effective Hamiltonian.