Quantitative Eliashberg theory of the superconductivity of thin films.

IF 2.3 4区 物理与天体物理 Q3 PHYSICS, CONDENSED MATTER
Giovanni Alberto Ummarino, Alessio Zaccone
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引用次数: 0

Abstract

A quantitative theory of the superconductivity of materials confined at the nanoscale in parameter-free agreement with experimental data has been missing so far. We present a generalization, in the Eliashberg framework, of a BCS theory of superconductivity in good metals which are confined along one of the three spatial directions, such as thin films. In this formulation of the Eliashberg equations the approximation of taking the normal density of states as its value at the Fermi level has been removed. By numerically solving these new Eliashberg-type equations, we find the dependence of the superconducting critical temperatureTcon the confinement sizeL, in quantitative agreement with experimental data of Pb and Al thin films with no adjustable parameters. This quantitative agreement provides an indirect confirmation that, upon increasing the confinement, a crossover from a spherical-like Fermi surface, which contains two growing hole pockets caused by the confinement, to a strongly deformed Fermi surface, occurs. This topology of the Fermi sea is implemented in the new Eliashberg-type equations to reproduce the experimentally observed maximum in the critical superconducting temperature vs film thickness of ultra-thin Pb films.

薄膜超导的埃利亚斯伯格定量理论。
我们在埃利亚斯伯格框架内提出了一种关于沿三个空间方向之一受限的良好金属(如薄膜)超导性的 BCS 理论的概括。在埃利亚斯伯格方程的这一表述中,取消了将正常状态密度(DOS)作为费米级值的近似值。通过对这些新的埃利亚斯伯格方程进行数值求解,我们发现超导临界温度 $T_{c}$ 与约束尺寸 $L$ 的关系,与无可调参数的铅和铝薄膜的实验数据定量一致。这种定量一致间接证实了在增加约束时,会出现从包含两个因约束而不断增大的孔洞的球形费米面到强变形费米面的交叉。费米海的这种拓扑结构被应用于新的埃利亚斯伯格方程,以重现实验观察到的超薄铅薄膜临界超导温度与薄膜厚度的最大值。
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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来源期刊
Journal of Physics: Condensed Matter
Journal of Physics: Condensed Matter 物理-物理:凝聚态物理
CiteScore
5.30
自引率
7.40%
发文量
1288
审稿时长
2.1 months
期刊介绍: Journal of Physics: Condensed Matter covers the whole of condensed matter physics including soft condensed matter and nanostructures. Papers may report experimental, theoretical and simulation studies. Note that papers must contain fundamental condensed matter science: papers reporting methods of materials preparation or properties of materials without novel condensed matter content will not be accepted.
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