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Main Authors: Teramachi, Nanami, Hashimoto, Aoi, Nakaaki, Iku, Ooi, Shuuichi, Tachiki, Minoru, Arisawa, Shunichi, Seto, Yusuke, Sakurai, Takahiro, Ohta, Hitoshi, Valenta, Jaroslav, Tsujii, Naohito, Mori, Takao, Uchino, Takashi
Format: Preprint
Published: 2022
Subjects:
Online Access:https://arxiv.org/abs/2209.08493
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author Teramachi, Nanami
Hashimoto, Aoi
Nakaaki, Iku
Ooi, Shuuichi
Tachiki, Minoru
Arisawa, Shunichi
Seto, Yusuke
Sakurai, Takahiro
Ohta, Hitoshi
Valenta, Jaroslav
Tsujii, Naohito
Mori, Takao
Uchino, Takashi
author_facet Teramachi, Nanami
Hashimoto, Aoi
Nakaaki, Iku
Ooi, Shuuichi
Tachiki, Minoru
Arisawa, Shunichi
Seto, Yusuke
Sakurai, Takahiro
Ohta, Hitoshi
Valenta, Jaroslav
Tsujii, Naohito
Mori, Takao
Uchino, Takashi
contents The proximity effect in normal/superconductor heterostructures is an intriguing phenomenon in that the normal side takes on the properties of a superconductor with an induced gap. However, the structural and pinning properties of vortices inside the normal regions remain poorly understood. Here, we report structure and superconducting properties of a proximity-coupled Mg/MgO/MgB2 system with ~30 vol. % of superconducting MgB2, in which MgB2 nanograins are distributed in a fractal manner to form a proximity network with clean interfaces. Conductivity and magnetic measurements demonstrate that this proximity-coupled system acts as a fully phase coherent superconductor with isotropic pinning. Magneto-optical imaging also reveals a rather homogeneous flux density distribution with no apparent granularity. Furthermore, we observe quantized proximity vortices and their clustering behavior by scanning superconducting quantum interface device microscopy. These results show that in contrast to the case of conventional granular superconductors, the grain boundaries in the present sample carry high critical currents and have high vortex pinning efficiency, resulting in a robust phase coherent state irrespective of the low volume fraction of the MgB2 nanograins. This finding not only reveals the features of proximity-induced vortices, but also demonstrates an excellent phase-locked capability of the proximity-coupled fractal system.
format Preprint
id arxiv_https___arxiv_org_abs_2209_08493
institution arXiv
publishDate 2022
record_format arxiv
spellingShingle Strong phase coherence and vortex matter in a fractal system with proximity-induced superconductivity
Teramachi, Nanami
Hashimoto, Aoi
Nakaaki, Iku
Ooi, Shuuichi
Tachiki, Minoru
Arisawa, Shunichi
Seto, Yusuke
Sakurai, Takahiro
Ohta, Hitoshi
Valenta, Jaroslav
Tsujii, Naohito
Mori, Takao
Uchino, Takashi
Superconductivity
The proximity effect in normal/superconductor heterostructures is an intriguing phenomenon in that the normal side takes on the properties of a superconductor with an induced gap. However, the structural and pinning properties of vortices inside the normal regions remain poorly understood. Here, we report structure and superconducting properties of a proximity-coupled Mg/MgO/MgB2 system with ~30 vol. % of superconducting MgB2, in which MgB2 nanograins are distributed in a fractal manner to form a proximity network with clean interfaces. Conductivity and magnetic measurements demonstrate that this proximity-coupled system acts as a fully phase coherent superconductor with isotropic pinning. Magneto-optical imaging also reveals a rather homogeneous flux density distribution with no apparent granularity. Furthermore, we observe quantized proximity vortices and their clustering behavior by scanning superconducting quantum interface device microscopy. These results show that in contrast to the case of conventional granular superconductors, the grain boundaries in the present sample carry high critical currents and have high vortex pinning efficiency, resulting in a robust phase coherent state irrespective of the low volume fraction of the MgB2 nanograins. This finding not only reveals the features of proximity-induced vortices, but also demonstrates an excellent phase-locked capability of the proximity-coupled fractal system.
title Strong phase coherence and vortex matter in a fractal system with proximity-induced superconductivity
topic Superconductivity
url https://arxiv.org/abs/2209.08493