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Main Authors: Zhakina, Elina, Turnbull, Luke, Xu, Weijie, König, Markus, Simon, Paul, Carrillo-Cabrera, Wilder, Fernandez-Pacheco, Amalio, Vool, Uri, Suess, Dieter, Abert, Claas, Fomin, Vladimir M., Donnelly, Claire
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2404.12151
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author Zhakina, Elina
Turnbull, Luke
Xu, Weijie
König, Markus
Simon, Paul
Carrillo-Cabrera, Wilder
Fernandez-Pacheco, Amalio
Vool, Uri
Suess, Dieter
Abert, Claas
Fomin, Vladimir M.
Donnelly, Claire
author_facet Zhakina, Elina
Turnbull, Luke
Xu, Weijie
König, Markus
Simon, Paul
Carrillo-Cabrera, Wilder
Fernandez-Pacheco, Amalio
Vool, Uri
Suess, Dieter
Abert, Claas
Fomin, Vladimir M.
Donnelly, Claire
contents When materials are patterned in three dimensions, there exist opportunities to tailor and create functionalities associated with an increase in complexity, the breaking of symmetries, and the introduction of curvature and non-trivial topologies. For superconducting nanostructures, the extension to the third dimension may trigger the emergence of new physical phenomena, as well as advances in technologies. Here, we harness three-dimensional (3D) nanopatterning to fabricate and control the emergent properties of a 3D superconducting nanostructure. Not only are we able to demonstrate the existence and motion of superconducting vortices in 3D but, with simulations, we show that the confinement leads to a well-defined bending of the vortices within the volume of the structure. Moreover, we experimentally observe a strong geometrical anisotropy of the critical field, through which we achieve the reconfigurable coexistence of superconducting and normal states in our 3D superconducting architecture, and the local definition of weak links. In this way, we uncover an intermediate regime of nanosuperconductivity, where the vortex state is truly three-dimensional and can be designed and manipulated by geometrical confinement. This insight into the influence of 3D geometries on superconducting properties offers a route to local reconfigurable control for future computing devices, sensors, and quantum technologies.
format Preprint
id arxiv_https___arxiv_org_abs_2404_12151
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Vortex motion in reconfigurable three-dimensional superconducting nanoarchitectures
Zhakina, Elina
Turnbull, Luke
Xu, Weijie
König, Markus
Simon, Paul
Carrillo-Cabrera, Wilder
Fernandez-Pacheco, Amalio
Vool, Uri
Suess, Dieter
Abert, Claas
Fomin, Vladimir M.
Donnelly, Claire
Mesoscale and Nanoscale Physics
Superconductivity
When materials are patterned in three dimensions, there exist opportunities to tailor and create functionalities associated with an increase in complexity, the breaking of symmetries, and the introduction of curvature and non-trivial topologies. For superconducting nanostructures, the extension to the third dimension may trigger the emergence of new physical phenomena, as well as advances in technologies. Here, we harness three-dimensional (3D) nanopatterning to fabricate and control the emergent properties of a 3D superconducting nanostructure. Not only are we able to demonstrate the existence and motion of superconducting vortices in 3D but, with simulations, we show that the confinement leads to a well-defined bending of the vortices within the volume of the structure. Moreover, we experimentally observe a strong geometrical anisotropy of the critical field, through which we achieve the reconfigurable coexistence of superconducting and normal states in our 3D superconducting architecture, and the local definition of weak links. In this way, we uncover an intermediate regime of nanosuperconductivity, where the vortex state is truly three-dimensional and can be designed and manipulated by geometrical confinement. This insight into the influence of 3D geometries on superconducting properties offers a route to local reconfigurable control for future computing devices, sensors, and quantum technologies.
title Vortex motion in reconfigurable three-dimensional superconducting nanoarchitectures
topic Mesoscale and Nanoscale Physics
Superconductivity
url https://arxiv.org/abs/2404.12151