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Published February 15, 2025 | Published
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Incommensurate broken helix induced by nonstoichiometry in the axion insulator candidate EuIn₂As₂

Gen, Masaki1 ORCID icon
Fujishiro, Yukako1
Okigami, Kazuki2 ORCID icon
Hayami, Satoru3 ORCID icon
Birch, Max T.1
Adachi, Kiyohiro1 ORCID icon
Hashizume, Daisuke1 ORCID icon
Kurumaji, Takashi2, 4 ORCID icon
Sagayama, Hajime5
Nakao, Hironori5 ORCID icon
Tokura, Yoshinori1
Arima, Taka-hisa1 ORCID icon
  • 1. ROR icon RIKEN Center for Emergent Matter Science
  • 2. ROR icon University of Tokyo
  • 3. ROR icon Hokkaido University
  • 4. ROR icon California Institute of Technology
  • 5. ROR icon High Energy Accelerator Research Organization

Abstract

Zintl phase EuIn2⁢As2 has garnered growing attention as an axion insulator candidate, triggered by the identification of a commensurate double-𝐐 broken-helix state in previous studies, however, its periodicity and symmetry remain subjects of debate. Here, we perform resonant x-ray scattering experiments on EuIn2⁢As2, revealing an incommensurate nature of the broken-helix state, where both the wave number and the amplitude of the helical modulation exhibit systematic sample dependence. Furthermore, the application of an in-plane magnetic field brings about a fanlike state that appears to preserve the double-𝐐 nature, which might be attributed to multiple-spin interactions in momentum space. We propose that the itinerant character of EuIn2⁢As2, most likely induced by Eu deficiency, gives rise to the helical modulation and impedes the realization of a theoretically predicted axion state with the collinear antiferromagnetic order.

Copyright and License

©2025 American Physical Society.

Acknowledgement

This work was financially supported by the JSPS KAKENHI Grants-In-Aid for Scientific Research (Grants No. 22H00101, No. 22K14011, No. 23H04869, No. 23H05431, and No. 23K13068), JST SPRING (Grant No. JPMJSP2108), and JST PRESTO (Grant No. MJPR20L8). The resonant x-ray scattering experiments were performed with the approval of the Photon Factory Program Advisory Committee (Proposals No. 2022G551 and No. 2023G093). The authors appreciate A. Kikkawa and M. Kriener for the invaluable support in the synthesis of the single crystals used in this study. The authors appreciate H. Takeda, S. Kitou, M. Hirschberger, and K. Kakurai for fruitful discussions.

Supplemental Material

Supplemental Material includes details of experimental methods and analyses.

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Additional details

Funding Dates Caltech Custom Metadata
Created:
February 19, 2025
Modified:
February 19, 2025