Xu Xiao Yan, Hong Liu Zi, Pan Gaopei, Qi Yang, Sun Kai, Meng Zi Yang
Department of Physics, Hong Kong University of Science and Technology, Clear Water Bay, Hong Kong, People's Republic of China.
J Phys Condens Matter. 2019 Nov 20;31(46):463001. doi: 10.1088/1361-648X/ab3295. Epub 2019 Aug 19.
This review summarizes recent developments in the study of fermionic quantum criticality, focusing on new progress in numerical methodologies, especially quantum Monte Carlo methods, and insights that emerged from recently large-scale numerical simulations. Quantum critical phenomena in fermionic systems have attracted decades of extensive research efforts, partially lured by their exotic properties and potential technology applications, and partially awakened by the profound and universal fundamental principles that govern these quantum critical systems. Due to the complex and non-perturbative nature, these systems face the most difficult and challenging problems in the study of modern condensed matter physics, and many important fundamental problems remain open. Recently, new developments in model design and algorithm improvements enabled unbiased large-scale numerical solutions to be achieved in the close vicinity of these quantum critical points, which paves a new pathway towards achieving controlled conclusions through combined efforts of theoretical and numerical studies, as well as possible theoretical guidance for experiments in heavy-fermion compounds, Cu-based and Fe-based superconductors, ultra-cold fermionic atomic gas, twisted graphene layers, etc, where signatures of fermionic quantum criticality exist.
本综述总结了费米子量子临界性研究的最新进展,重点关注数值方法,特别是量子蒙特卡罗方法的新进展,以及最近大规模数值模拟中出现的见解。费米子系统中的量子临界现象吸引了数十年的广泛研究努力,部分原因是其奇异特性和潜在的技术应用,部分原因是支配这些量子临界系统的深刻而普遍的基本原理。由于其复杂和非微扰的性质,这些系统面临着现代凝聚态物理研究中最困难和最具挑战性的问题,许多重要的基本问题仍然悬而未决。最近,模型设计和算法改进方面的新进展使得在这些量子临界点附近能够实现无偏的大规模数值解,这为通过理论和数值研究的共同努力得出可控结论开辟了一条新途径,也为在重费米子化合物、铜基和铁基超导体、超冷费米子原子气体、扭曲石墨烯层等存在费米子量子临界性特征的体系中进行实验提供了可能的理论指导。
