Some analytical solutions for magnetic flux distribution in long Josephson junction with second harmonic in the current phase relation

APPLICATION OF MATHEMATICS IN TECHNICAL AND NATURAL SCIENCES: 11th International Conference for Promoting the Application of Mathematics in Technical and Natural Sciences - AMiTaNS’19 Pub Date : 2019-10-24 DOI:10.1063/1.5130838

H. Dimov, P. Atanasova, S. A. Panayotova

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引用次数: 1

Abstract

In the current work long Josephson junctions are being studied. Magnetic flux distribution is the physical measure for phase difference of the wave functions in the superconducting layers of the junction. The current phase relation, in most cases, can be considered as an odd strict 2π-periodic function, and hence, it can be presented in Fourier series of sinuses. It is well-known from the physical experiment that with a sufficient degree of precision, a number of physical systems are reliably described with the contribution of only first two harmonics. The adequate mathematical model for the distribution of the magnetic flux is then the double sine-Gordon equation with Neumann boundary conditions at the ends of the junction. Even in the stationary case, the boundary problem is highly nonlinear and the only tool for its comprehensive study is numerical methods. The aim of the present work is to show that in the case of zero external current, the stationary equation turns out to be a fully integrable model, derived from a variation principle with a cosine potential. In our work analytical solutions for the magnetic flux distributions described in the terms of Jacobi elliptic sinuses are derived. Analytical studies in this case serve to further numerically study of this multiparametric nonlinear boundary problem, which is so important in the applied nanophysics.In the current work long Josephson junctions are being studied. Magnetic flux distribution is the physical measure for phase difference of the wave functions in the superconducting layers of the junction. The current phase relation, in most cases, can be considered as an odd strict 2π-periodic function, and hence, it can be presented in Fourier series of sinuses. It is well-known from the physical experiment that with a sufficient degree of precision, a number of physical systems are reliably described with the contribution of only first two harmonics. The adequate mathematical model for the distribution of the magnetic flux is then the double sine-Gordon equation with Neumann boundary conditions at the ends of the junction. Even in the stationary case, the boundary problem is highly nonlinear and the only tool for its comprehensive study is numerical methods. The aim of the present work is to show that in the case of zero external current, the stationary equation turns out to be a fully integrable model,...

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电流相位关系中含二次谐波的长约瑟夫森结磁通分布的解析解

在目前的工作中，长约瑟夫森结正在被研究。磁通分布是对结超导层中波函数相位差的物理度量。在大多数情况下，电流相位关系可以看作是一个奇严格2π周期函数，因此，它可以用正弦的傅里叶级数表示。从物理实验中我们知道，只要有足够的精度，只要有前两个谐波的贡献，就可以可靠地描述许多物理系统。磁通分布的适当数学模型是结点两端具有诺伊曼边界条件的双正弦戈登方程。即使在平稳情况下，边界问题也是高度非线性的，全面研究它的唯一工具就是数值方法。本工作的目的是表明，在零外部电流的情况下，平稳方程原来是一个完全可积的模型，推导出与余弦势的变化原理。在我们的工作中，给出了用雅可比椭圆窦描述的磁通分布的解析解。本文的分析研究有助于进一步对多参数非线性边界问题进行数值研究，这在应用纳米物理学中是非常重要的。在目前的工作中，长约瑟夫森结正在被研究。磁通分布是对结超导层中波函数相位差的物理度量。在大多数情况下，电流相位关系可以看作是一个奇严格2π周期函数，因此，它可以用正弦的傅里叶级数表示。从物理实验中我们知道，只要有足够的精度，只要有前两个谐波的贡献，就可以可靠地描述许多物理系统。磁通分布的适当数学模型是结点两端具有诺伊曼边界条件的双正弦戈登方程。即使在平稳情况下，边界问题也是高度非线性的，全面研究它的唯一工具就是数值方法。本文的目的是证明在零外部电流的情况下，平稳方程是一个完全可积的模型。

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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APPLICATION OF MATHEMATICS IN TECHNICAL AND NATURAL SCIENCES: 11th International Conference for Promoting the Application of Mathematics in Technical and Natural Sciences - AMiTaNS’19

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