Parallel magnetic field suppresses dissipation in superconducting nanostrips

Parallel magnetic field suppresses dissipation in superconducting nanostrips

The motion of Abrikosov vortices in type-II superconductors results in a finite resistance in the presence of an applied electric current. Elimination or reduction of the resistance via immobilization of vortices is the "holy grail" of superconductivity research. Common wisdom dictates tha...

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Bibliographic Details
Published in:Proceedings of the National Academy of Sciences - PNAS Vol. 114; no. 48
Main Authors: Wang, Yong-Lei, Glatz, Andreas, Kimmel, Gregory J., Aranson, Igor S., Thoutam, Laxman R., Xiao, Zhi-Li, Berdiyorov, Golibjon R., Peeters, François M., Crabtree, George W., Kwok, Wai-Kwong
Format: Journal Article
Language:English
Published: United States National Academy of Sciences, Washington, DC (United States) 13-11-2017
Subjects:
CONDENSED MATTER PHYSICS, SUPERCONDUCTIVITY AND SUPERFLUIDITY
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Summary:The motion of Abrikosov vortices in type-II superconductors results in a finite resistance in the presence of an applied electric current. Elimination or reduction of the resistance via immobilization of vortices is the "holy grail" of superconductivity research. Common wisdom dictates that an increase in the magnetic field escalates the loss of energy since the number of vortices increases. Here we show that this is no longer true if the magnetic field and the current are applied parallel to each other. Our experimental studies on the resistive behavior of a superconducting Mo0.79Ge0.21 nanostrip reveal the emergence of a dissipative state with increasing magnetic field, followed by a pronounced resistance drop, signifying a reentrance to the superconducting state. Large-scale simulations of the 3D time-dependent Ginzburg-Landau model indicate that the intermediate resistive state is due to an unwinding of twisted vortices. When the magnetic field increases, this instability is suppressed due to a better accommodation of the vortex lattice to the pinning configuration. Our findings show that magnetic field and geometrical confinement can suppress the dissipation induced by vortex motion and thus radically improve the performance of superconducting materials.
Bibliography:USDOE Office of Science - Office of Advanced Scientific Computing Research
USDOE Office of Science - Office of Basic Energy Sciences - Materials Sciences and Engineering Division
AC02-06CH11357
National Science Foundation (NSF)
ISSN:0027-8424
1091-6490