Dissociation of composite Abrikosov vortices in two-band superconductors in a strong rf field

Pub Date : 2024-02-22 DOI:10.1063/10.0024321
A. O. Pokusinskyi, A. L. Kasatkin
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Abstract

In several theoretical works, it was argued that under certain conditions Abrikosov vortices in multiband superconductors can split and exist in the form of fractional vortices, formed separately in superfluid condensates of different electron bands. Such vortices possess a fractional flux quantum, and these fractional vortices attract each other, trying to join into a composite vortex with the whole flux quantum ϕ0=h/2e. In the present work, we solve numerically the nonlinear dynamic equation for the composite vortex, settled in the pinning potential well of the columnar defect within a two-band superconductor, and exerted the rf Lorentz force action. We demonstrate that at high enough rf current amplitudes such composite Abrikosov vortices will dissociate into fractional ones and escape from the pinning potential well. The sequence of these events depends on the character of the pinning potential well, e.g., the radius of the pinning potential well. The possible manifestation of such kind transitions in rf electrodynamic characteristics, such as a complex rf resistivity and harmonics generation is calculated.
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强射频场下双带超导体中复合阿布里科索夫涡旋的解离
一些理论著作认为,在某些条件下,多带超导体中的阿布里科索夫漩涡可以分裂,并以分数漩涡的形式存在,分别形成于不同电子带的超流体凝聚物中。这种漩涡具有分数通量,这些分数漩涡相互吸引,试图结合成一个具有整体通量ϕ0=h/2e的复合漩涡。在本研究中,我们数值求解了复合漩涡的非线性动力学方程,该漩涡沉降在双带超导体内柱状缺陷的针状势阱中,并施加了射频洛伦兹力作用。我们证明,在足够高的射频电流幅值下,这种复合阿布里科索夫涡旋会解离成分数涡旋,并从钉势阱中逃逸出来。这些事件的发生顺序取决于针刺势阱的特性,例如针刺势阱的半径。我们计算了这种转变在射频电动特性中可能的表现,如复合射频电阻率和谐波的产生。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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