Fermi surface origin of the low-temperature magnetoresistance anomaly

IF 17.3 1区材料科学 Q1 MATERIALS SCIENCE, MULTIDISCIPLINARY

Matter Pub Date : 2025-07-02 DOI:10.1016/j.matt.2025.102105

Yejun Feng , Yishu Wang , Thomas F. Rosenbaum , Peter B. Littlewood , Hua Chen

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Abstract

Magnetoresistance (MR) at a fixed field can demonstrate a non-monotonic temperature dependence—an anomaly—in many systems, including low-dimensional chalcogenides, spin- and charge-density-wave metals, and topological semimetals. These systems are often low-carrier-density compensated metals, and the physics are expected to be quasi-classical. Nevertheless, the MR anomaly also exists in the highly conductive metals Cr, Mo, and W for both linear and quadratic field dependence, with their non-saturation attributed to either open orbit or electron-hole compensation. We argue that quantum transport across sharp Fermi surface arcs, but not necessarily the full cyclotron orbit, governs this MR anomaly, thereby accounting for the profound effects of disorder. In Cr, an overlay exists between three temperature dependences: MR at a constant high field, linear MR at a low field, and Shubnikov-de Haas (SdH) oscillations of the smallest orbit. In Mo, the MR anomaly extends beyond the temperature of its SdH oscillations but disappears before Kohler’s scaling reemerges.

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费米表面低温磁阻异常的起源

固定场下的磁阻（MR）可以在许多系统中表现出非单调的温度依赖性——一种异常，包括低维硫族化合物、自旋和电荷密度波金属以及拓扑半金属。这些系统通常是低载流子密度补偿金属，并且物理预期是准经典的。然而，高导电性金属Cr、Mo和W也存在线性和二次场依赖的MR异常，其不饱和归因于开轨道或电子-空穴补偿。我们认为，通过尖锐费米表面弧线的量子输运，而不一定是整个回旋加速器轨道，控制着这种磁共振异常，从而解释了无序的深刻影响。在Cr中，三种温度依赖性之间存在覆盖层：恒定高场下的磁共振，低场下的线性磁共振，以及最小轨道的舒布尼科夫-德哈斯（SdH）振荡。在Mo中，MR异常超出了其SdH振荡的温度，但在Kohler标度重新出现之前消失。

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

Matter MATERIALS SCIENCE, MULTIDISCIPLINARY-

CiteScore

26.30

自引率

2.60%

发文量

367

期刊介绍： Matter, a monthly journal affiliated with Cell, spans the broad field of materials science from nano to macro levels,covering fundamentals to applications. Embracing groundbreaking technologies,it includes full-length research articles,reviews, perspectives,previews, opinions, personnel stories, and general editorial content. Matter aims to be the primary resource for researchers in academia and industry, inspiring the next generation of materials scientists.