EuAuSb: An odd-parity helical variation of altermagnetism

J. Sears; Juntao Yao; Zhixiang Hu; Wei Tian; Niraj Aryal; Weiguo Yin; A. M. Tsvelik; I. A. Zaliznyak; Qiang Li; J. M. Tranquada

doi:10.1103/k376-4cxw

EuAuSb: An odd-parity helical variation of altermagnetism

J. Sears
, Juntao Yao
, Zhixiang Hu
, Wei Tian
, Niraj Aryal
, Weiguo Yin
, A. M. Tsvelik
, I. A. Zaliznyak
, Qiang Li
, J. M. Tranquada

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Research output: Contribution to journal › Article › peer-review

Abstract

EuAuSb is a triangular-lattice Dirac semimetal in which a topological Hall effect has been observed to develop in association with a magnetically ordered phase. Our single-crystal neutron diffraction measurements have identified an incommensurate helical order in which individual ferromagnetic Eu2+ layers rotate in-plane by ∼120◦ from one layer to the next. An in-plane magnetic field distorts the incommensurate order, eventually leading to a first order transition to a state that is approximately commensurate and that is continuously polarized as the bulk magnetization approaches saturation. From an analysis of the magnetic diffraction intensities versus field, we find evidence for a dip in the ordered in-plane moment at the same field where the topological Hall effect is a maximum, and we propose that this is due to field-induced quantum spin fluctuations. Our electronic structure calculations yield exchange constants compatible with the helical order and show that the bands near the Fermi level lose their spin degeneracy via a mechanism similar to that in the collinear altermagnets. We find that, unlike the even symmetry seen in the altermagnets, the spin splitting in EuAuSb has odd-wave symmetry similar to that recently found in a number of coplanar magnetic materials.

Original language	English
Pages (from-to)	944551-944559
Number of pages	9
Journal	Physical Review B
Volume	112
Issue number	9
DOIs	https://doi.org/10.1103/k376-4cxw
State	Published - Sep 26 2025

Funding

J.M.T. and I.Z. acknowledge helpful discussions with I. I. Mazin, and J.S. and J.M.T. acknowledge insightful comments from R. M. Fernandes. Work at Brookhaven is supported by the Office of Basic Energy Sciences, Materials Sciences and Engineering Division, U.S. Department of Energy (DOE) under Contract No. DE-SC0012704. A portion of this research used resources at the High Flux Isotope Reactor, a DOE Office of Science User Facility operated by Oak Ridge National Laboratory. ORNL is managed by UTBattelle, LLC, under contract DE-AC05-00OR22725 with the U.S. Department of Energy (DOE). The beam time on VERITAS was allocated under Proposal No. IPTS-32817.

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title = "EuAuSb: An odd-parity helical variation of altermagnetism",

abstract = "EuAuSb is a triangular-lattice Dirac semimetal in which a topological Hall effect has been observed to develop in association with a magnetically ordered phase. Our single-crystal neutron diffraction measurements have identified an incommensurate helical order in which individual ferromagnetic Eu2+ layers rotate in-plane by ∼120◦ from one layer to the next. An in-plane magnetic field distorts the incommensurate order, eventually leading to a first order transition to a state that is approximately commensurate and that is continuously polarized as the bulk magnetization approaches saturation. From an analysis of the magnetic diffraction intensities versus field, we find evidence for a dip in the ordered in-plane moment at the same field where the topological Hall effect is a maximum, and we propose that this is due to field-induced quantum spin fluctuations. Our electronic structure calculations yield exchange constants compatible with the helical order and show that the bands near the Fermi level lose their spin degeneracy via a mechanism similar to that in the collinear altermagnets. We find that, unlike the even symmetry seen in the altermagnets, the spin splitting in EuAuSb has odd-wave symmetry similar to that recently found in a number of coplanar magnetic materials.",

author = "J. Sears and Juntao Yao and Zhixiang Hu and Wei Tian and Niraj Aryal and Weiguo Yin and Tsvelik, \{A. M.\} and Zaliznyak, \{I. A.\} and Qiang Li and Tranquada, \{J. M.\}",

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doi = "10.1103/k376-4cxw",

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AU - Sears, J.

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AU - Tian, Wei

AU - Aryal, Niraj

AU - Yin, Weiguo

AU - Tsvelik, A. M.

AU - Zaliznyak, I. A.

AU - Li, Qiang

AU - Tranquada, J. M.

PY - 2025/9/26

Y1 - 2025/9/26

N2 - EuAuSb is a triangular-lattice Dirac semimetal in which a topological Hall effect has been observed to develop in association with a magnetically ordered phase. Our single-crystal neutron diffraction measurements have identified an incommensurate helical order in which individual ferromagnetic Eu2+ layers rotate in-plane by ∼120◦ from one layer to the next. An in-plane magnetic field distorts the incommensurate order, eventually leading to a first order transition to a state that is approximately commensurate and that is continuously polarized as the bulk magnetization approaches saturation. From an analysis of the magnetic diffraction intensities versus field, we find evidence for a dip in the ordered in-plane moment at the same field where the topological Hall effect is a maximum, and we propose that this is due to field-induced quantum spin fluctuations. Our electronic structure calculations yield exchange constants compatible with the helical order and show that the bands near the Fermi level lose their spin degeneracy via a mechanism similar to that in the collinear altermagnets. We find that, unlike the even symmetry seen in the altermagnets, the spin splitting in EuAuSb has odd-wave symmetry similar to that recently found in a number of coplanar magnetic materials.

AB - EuAuSb is a triangular-lattice Dirac semimetal in which a topological Hall effect has been observed to develop in association with a magnetically ordered phase. Our single-crystal neutron diffraction measurements have identified an incommensurate helical order in which individual ferromagnetic Eu2+ layers rotate in-plane by ∼120◦ from one layer to the next. An in-plane magnetic field distorts the incommensurate order, eventually leading to a first order transition to a state that is approximately commensurate and that is continuously polarized as the bulk magnetization approaches saturation. From an analysis of the magnetic diffraction intensities versus field, we find evidence for a dip in the ordered in-plane moment at the same field where the topological Hall effect is a maximum, and we propose that this is due to field-induced quantum spin fluctuations. Our electronic structure calculations yield exchange constants compatible with the helical order and show that the bands near the Fermi level lose their spin degeneracy via a mechanism similar to that in the collinear altermagnets. We find that, unlike the even symmetry seen in the altermagnets, the spin splitting in EuAuSb has odd-wave symmetry similar to that recently found in a number of coplanar magnetic materials.

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EuAuSb: An odd-parity helical variation of altermagnetism

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