Superconducting Quantum Critical Phenomena

Reports in Advances of Physical Sciences Pub Date : 2018-09-01 DOI:10.1142/S2424942418500093

Y. Tao

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Abstract

When the superconducting transition temperature [Formula: see text] sufficiently approaches zero, quantum fluctuations are expected to be overwhelmingly amplified around zero temperature so that the mean-field approximation may break down. This implies that quantum critical phenomena may emerge in highly underdoped and overdoped regions, where the transition temperature [Formula: see text] is sufficiently low. By using Gor’kov’s Green function method, we propose a superconducting quantum critical equation (SQCE) for describing such critical phenomena. For two-dimensional (2D) overdoped materials, SQCE shows that the transition temperature [Formula: see text] and the zero-temperature superfluid phase stiffness [Formula: see text] will obey a two-class scaling combined by linear and parabolic parts, which agrees with the existing experimental investigation [I. Božović et al., Dependence of the critical temperature in overdoped copper oxides on superfluid density, Nature 536 (2016) 309–311]. For three-dimensional (3D) overdoped materials, SQCE predicts that the two-class scaling will be replaced by the linear scaling. Furthermore, we show that SQCE can be applied into highly underdoped region by using Anderson’s non-Fermi liquid model.

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超导量子临界现象

当超导转变温度[公式:见原文]充分接近于零时，预计量子涨落将在零温度附近被压倒性地放大，从而使平均场近似可能失效。这意味着在高度欠掺杂和过掺杂的区域可能出现量子临界现象，其中转变温度[公式:见文本]足够低。利用Gor’kov’s Green函数方法，我们提出了超导量子临界方程(SQCE)来描述这种临界现象。对于二维(2D)过掺杂材料，SQCE表明转变温度[公式:见文]和零温度超流体相刚度[公式:见文]服从线性部分和抛物线部分组合的两级标度，这与已有的实验研究[1]一致。Božović et al.，过掺杂铜氧化物临界温度对超流体密度的依赖性，Nature 536(2016) 309-311。对于三维(3D)过掺杂材料，SQCE预测两级标度将被线性标度所取代。此外，我们还利用Anderson的非费米液体模型证明了SQCE可以应用于高欠掺杂区域。

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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Reports in Advances of Physical Sciences

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3 weeks