磁量子临界性：动态均场视角

arXiv - PHYS - Strongly Correlated Electrons Pub Date : 2024-09-06 DOI:arxiv-2409.04308

S. Adler, D. R. Fus, M. O. Malcolms, A. Vock, K. Held, A. A. Katanin, T. Schäfer, A. Toschi

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引用次数: 0

摘要

我们在动态均场理论的层面上研究了体相关金属的磁量子相变。为此，我们重点研究了简单立方晶格上的哈伯德模型与温度和电子密度的函数关系，确定了其磁转变的不同状态--经典、量子临界和量子无序--以及相应的临界指数。我们的数值结果，连同支持的均场推导，证明了底层费米面上科恩反常现象的存在不仅推动了量子临界点以上的量子临界行为，还塑造了它周围的整个相图。最后，在概述了不同费米面几何形状对量子临界的影响之后，我们讨论了动力学均场之外的空间相关性可能在多大程度上改变我们的发现。

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Magnetic quantum criticality: dynamical mean-field perspective

We investigate the magnetic quantum phase-transitions in bulk correlated metals at the level of dynamical mean-field theory. To this end, we focus on the Hubbard model on a simple cubic lattice as a function of temperature and electronic density, determining the different regimes of its magnetic transition - classical, quantum critical, and quantum disordered - as well as the corresponding critical exponents. Our numerical results, together with supporting mean-field derivations, demonstrate how the presence of Kohn-anomalies on the underlying Fermi surface does not only drive the quantum critical behavior above the quantum critical point, but shapes the whole phase diagram around it. Finally, after outlining the impact of different Fermi surface geometries on quantum criticality, we discuss to what extent spatial correlations beyond dynamical mean-field might modify our findings.

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arXiv - PHYS - Strongly Correlated Electrons

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