The local rupture of the superconductivity and the curvature of the mesoscopic sample

IF 1.3 3区物理与天体物理 Q4 PHYSICS, APPLIED Physica C-superconductivity and Its Applications Pub Date : 2024-01-13 DOI:10.1016/j.physc.2024.1354436

Isaías G. de Oliveira, Jonathan S. de Morais, Paloma F. Ferreira

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Abstract

In this article we revisit a well-known effect in superconductors, which is the penetration of the magnetic field by regions of greater radius of curvature (Tinkham, 2008; De Gennes, 1966). This is exposed in the literature but without a quantitative solution. Here we solve this problem by two distinct numerical simulations. We calculate the superconducting current density using numerical simulations via the London theory in the Meissner state and numerical simulations using the time-dependent Ginzburg–Landau (TDGL) theory for the vortex state. In both simulations, the results obtained are in agreement, as could not be otherwise. We show that in the Meissner state the current density increases much faster in the region where the radius of curvature is larger, thus reaching the critical value first in this location, and therefore local breakdown of superconductivity occurs. In the vortex state, our simulations, using TDGL, show that the vortices penetrate through exactly the same location pointed out by the previous simulation. For this study we worked with a superconducting needle with an ellipsoidal mesoscopic cross section.

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超导的局部断裂和介观样品的曲率

在本文中，我们将重温超导体中的一个著名效应，即曲率半径较大的区域对磁场的穿透（Tinkham，2008 年；De Gennes，1966 年）。这种现象在文献中有所提及，但没有定量的解决方案。在这里，我们通过两种不同的数值模拟来解决这个问题。在迈斯纳状态下，我们通过伦敦理论进行数值模拟计算超导电流密度；在涡旋状态下，我们通过时间依赖金兹堡-朗道（TDGL）理论进行数值模拟计算超导电流密度。在这两种模拟中，得到的结果都是一致的，这一点是不可能的。我们的研究表明，在迈斯纳态中，曲率半径较大的区域电流密度增加得更快，因此在该区域首先达到临界值，从而发生局部超导击穿。在漩涡状态下，我们使用 TDGL 进行的模拟显示，漩涡穿透的位置与之前模拟所指出的位置完全相同。在这项研究中，我们使用了具有椭圆形介观横截面的超导针。

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来源期刊

Physica C-superconductivity and Its Applications 物理-物理：应用

CiteScore

2.70

自引率

11.80%

发文量

102

审稿时长

66 days

期刊介绍： Physica C (Superconductivity and its Applications) publishes peer-reviewed papers on novel developments in the field of superconductivity. Topics include discovery of new superconducting materials and elucidation of their mechanisms, physics of vortex matter, enhancement of critical properties of superconductors, identification of novel properties and processing methods that improve their performance and promote new routes to applications of superconductivity. The main goal of the journal is to publish: 1. Papers that substantially increase the understanding of the fundamental aspects and mechanisms of superconductivity and vortex matter through theoretical and experimental methods. 2. Papers that report on novel physical properties and processing of materials that substantially enhance their critical performance. 3. Papers that promote new or improved routes to applications of superconductivity and/or superconducting materials, and proof-of-concept novel proto-type superconducting devices. The editors of the journal will select papers that are well written and based on thorough research that provide truly novel insights.