由波动回路电流引起的超导性。

Superconductivity due to fluctuating loop currents.

作者信息

Palle Grgur, Ojajärvi Risto, Fernandes Rafael M, Schmalian Jörg

机构信息

Institute for Theoretical Condensed Matter Physics, Karlsruhe Institute of Technology, 76131 Karlsruhe, Germany.

School of Physics and Astronomy, University of Minnesota, Minneapolis, MN 55455, USA.

出版信息

Sci Adv. 2024 Jun 14;10(24):eadn3662. doi: 10.1126/sciadv.adn3662.

DOI:10.1126/sciadv.adn3662

PMID:38875341

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11177937/

Abstract

Orbital magnetism and the loop currents (LCs) that accompany it have been proposed to emerge in many systems, including cuprates, iridates, and kagome superconductors. In the case of cuprates, LCs have been put forward as the driving force behind the pseudogap, strange-metal behavior, and -wave superconductivity. Here, we investigate whether fluctuating intra-unit-cell LCs can cause unconventional superconductivity. For odd-parity LCs, we find that they are repulsive in all pairing channels near the underlying quantum-critical point (QCP). For even-parity LCs, their fluctuations give rise to unconventional pairing, which is not amplified in the vicinity of the QCP, in sharp contrast to pairing mediated by spin-magnetic, nematic, or ferroelectric fluctuations. Applying our formalism to the cuprates, we conclude that fluctuating intra-unit-cell LCs are unlikely to yield -wave superconductivity. If LCs are to be relevant for the cuprates, they must break translation symmetry.

摘要

轨道磁性及其伴随的回路电流（LCs）已被认为会出现在许多体系中，包括铜酸盐、铱酸盐和 Kagome 超导体。在铜酸盐的情况中，回路电流被提出是赝能隙、奇异金属行为和 d 波超导背后的驱动力。在此，我们研究单位晶胞内波动的回路电流是否会导致非常规超导。对于奇宇称回路电流，我们发现在潜在量子临界点（QCP）附近的所有配对通道中它们都是排斥的。对于偶宇称回路电流，其涨落会导致非常规配对，这种配对在量子临界点附近不会增强，这与由自旋磁、向列或铁电涨落介导的配对形成鲜明对比。将我们的形式体系应用于铜酸盐，我们得出结论，单位晶胞内波动的回路电流不太可能产生 d 波超导。如果回路电流与铜酸盐相关，它们必须破坏平移对称性。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/58a5/11177937/e141e153e09c/sciadv.adn3662-f1.jpg

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由波动回路电流引起的超导性。

Superconductivity due to fluctuating loop currents.

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