Author
Listed:
- Benjamin Schrunk
(Ames Laboratory)
- Yevhen Kushnirenko
(Ames Laboratory
Iowa State University)
- Brinda Kuthanazhi
(Ames Laboratory
Iowa State University)
- Junyeong Ahn
(Harvard University)
- Lin-Lin Wang
(Ames Laboratory)
- Evan O’Leary
(Ames Laboratory
Iowa State University)
- Kyungchan Lee
(Ames Laboratory
Iowa State University
Universität Würzburg
Universität Würzburg)
- Andrew Eaton
(Ames Laboratory
Iowa State University)
- Alexander Fedorov
(Leibniz Institute for Solid State and Materials Research
Helmholtz-Zentrum Berlin für Materialien und Energie)
- Rui Lou
(Leibniz Institute for Solid State and Materials Research
Lanzhou University)
- Vladimir Voroshnin
(Helmholtz-Zentrum Berlin für Materialien und Energie)
- Oliver J. Clark
(Helmholtz-Zentrum Berlin für Materialien und Energie)
- Jaime Sánchez-Barriga
(Helmholtz-Zentrum Berlin für Materialien und Energie)
- Sergey L. Bud’ko
(Ames Laboratory
Iowa State University)
- Robert-Jan Slager
(Harvard University
University of Cambridge)
- Paul C. Canfield
(Ames Laboratory
Iowa State University)
- Adam Kaminski
(Ames Laboratory
Iowa State University)
Abstract
The Fermi surface plays an important role in controlling the electronic, transport and thermodynamic properties of materials. As the Fermi surface consists of closed contours in the momentum space for well-defined energy bands, disconnected sections known as Fermi arcs can be signatures of unusual electronic states, such as a pseudogap1. Another way to obtain Fermi arcs is to break either the time-reversal symmetry2 or the inversion symmetry3 of a three-dimensional Dirac semimetal, which results in formation of pairs of Weyl nodes that have opposite chirality4, and their projections are connected by Fermi arcs at the bulk boundary3,5–12. Here, we present experimental evidence that pairs of hole- and electron-like Fermi arcs emerge below the Neel temperature (TN) in the antiferromagnetic state of cubic NdBi due to a new magnetic splitting effect. The observed magnetic splitting is unusual, as it creates bands of opposing curvature, which change with temperature and follow the antiferromagnetic order parameter. This is different from previous theoretically considered13,14 and experimentally reported cases15,16 of magnetic splitting, such as traditional Zeeman and Rashba, in which the curvature of the bands is preserved. Therefore, our findings demonstrate a type of magnetic band splitting in the presence of a long-range antiferromagnetic order that is not readily explained by existing theoretical ideas.
Suggested Citation
Benjamin Schrunk & Yevhen Kushnirenko & Brinda Kuthanazhi & Junyeong Ahn & Lin-Lin Wang & Evan O’Leary & Kyungchan Lee & Andrew Eaton & Alexander Fedorov & Rui Lou & Vladimir Voroshnin & Oliver J. Cla, 2022.
"Emergence of Fermi arcs due to magnetic splitting in an antiferromagnet,"
Nature, Nature, vol. 603(7902), pages 610-615, March.
Handle:
RePEc:nat:nature:v:603:y:2022:i:7902:d:10.1038_s41586-022-04412-x
DOI: 10.1038/s41586-022-04412-x
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Cited by:
- A. Honma & D. Takane & S. Souma & K. Yamauchi & Y. Wang & K. Nakayama & K. Sugawara & M. Kitamura & K. Horiba & H. Kumigashira & K. Tanaka & T. K. Kim & C. Cacho & T. Oguchi & T. Takahashi & Yoichi An, 2023.
"Antiferromagnetic topological insulator with selectively gapped Dirac cones,"
Nature Communications, Nature, vol. 14(1), pages 1-8, December.
- Zengle Huang & Hemian Yi & Daniel Kaplan & Lujin Min & Hengxin Tan & Ying-Ting Chan & Zhiqiang Mao & Binghai Yan & Cui-Zu Chang & Weida Wu, 2024.
"Hidden non-collinear spin-order induced topological surface states,"
Nature Communications, Nature, vol. 15(1), pages 1-8, December.
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