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Main Authors: Wang, Ruoqi, Li, Xinyang, Zhao, Bo, Wen, Haofu, Gu, Xin, Yuan, Shijun, Ling, Langsheng, Xi, Chuanying, Wang, Ze, Hong, Kunquan, Ma, Liang, Xia, Ke, Chen, Taishi, Wang, Jinlan
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2603.29138
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author Wang, Ruoqi
Li, Xinyang
Zhao, Bo
Wen, Haofu
Gu, Xin
Yuan, Shijun
Ling, Langsheng
Xi, Chuanying
Wang, Ze
Hong, Kunquan
Ma, Liang
Xia, Ke
Chen, Taishi
Wang, Jinlan
author_facet Wang, Ruoqi
Li, Xinyang
Zhao, Bo
Wen, Haofu
Gu, Xin
Yuan, Shijun
Ling, Langsheng
Xi, Chuanying
Wang, Ze
Hong, Kunquan
Ma, Liang
Xia, Ke
Chen, Taishi
Wang, Jinlan
contents Topologically non-trivial nodes emerging from flat-band crossings not only enhance unconventional topological responses but also play a fundamental role in exploring correlation-driven topological physics. Here, we report the exceptionally robust chiral-anomaly-dominated transport in D0_3-Fe_3Ga. First, we observe a combination of positive and negative magnetoresistance, ideal planar longitudinal magnetoresistance (PLMR), and the planar Hall effect (PHE). Second, ultra-low-temperature resistivity exhibits pronounced non-Fermi-liquid (NFL) behavior, accompanied by the emergence of giant intrinsic anomalous Hall conductivity (AHC), in excellent agreement with our DFT calculations, which confirm the existence of tilted Weyl points arising from crossings of nearly three-dimensional (3D) flat bands. Most remarkably, we detect an exceptionally robust flat magnetoresistance (flat-MR) that persists without decay up to 33 T. This set of phenomena provides strong evidence that the Fermi level intersects the flattened Weyl crossings, offering confirmation of a topological flat-band semimetal. D0_3-Fe_3Ga presents a promising magnetic platform for quantum device innovations.
format Preprint
id arxiv_https___arxiv_org_abs_2603_29138
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Robust Flat Magnetoresistivity in D0$_3$-Fe$_3$Ga Driven by Chiral Anomaly
Wang, Ruoqi
Li, Xinyang
Zhao, Bo
Wen, Haofu
Gu, Xin
Yuan, Shijun
Ling, Langsheng
Xi, Chuanying
Wang, Ze
Hong, Kunquan
Ma, Liang
Xia, Ke
Chen, Taishi
Wang, Jinlan
Materials Science
Strongly Correlated Electrons
Topologically non-trivial nodes emerging from flat-band crossings not only enhance unconventional topological responses but also play a fundamental role in exploring correlation-driven topological physics. Here, we report the exceptionally robust chiral-anomaly-dominated transport in D0_3-Fe_3Ga. First, we observe a combination of positive and negative magnetoresistance, ideal planar longitudinal magnetoresistance (PLMR), and the planar Hall effect (PHE). Second, ultra-low-temperature resistivity exhibits pronounced non-Fermi-liquid (NFL) behavior, accompanied by the emergence of giant intrinsic anomalous Hall conductivity (AHC), in excellent agreement with our DFT calculations, which confirm the existence of tilted Weyl points arising from crossings of nearly three-dimensional (3D) flat bands. Most remarkably, we detect an exceptionally robust flat magnetoresistance (flat-MR) that persists without decay up to 33 T. This set of phenomena provides strong evidence that the Fermi level intersects the flattened Weyl crossings, offering confirmation of a topological flat-band semimetal. D0_3-Fe_3Ga presents a promising magnetic platform for quantum device innovations.
title Robust Flat Magnetoresistivity in D0$_3$-Fe$_3$Ga Driven by Chiral Anomaly
topic Materials Science
Strongly Correlated Electrons
url https://arxiv.org/abs/2603.29138