Nature Communications (May 2023)

Giant electrically tunable magnon transport anisotropy in a van der Waals antiferromagnetic insulator

  • Shaomian Qi,
  • Di Chen,
  • Kangyao Chen,
  • Jianqiao Liu,
  • Guangyi Chen,
  • Bingcheng Luo,
  • Hang Cui,
  • Linhao Jia,
  • Jiankun Li,
  • Miaoling Huang,
  • Yuanjun Song,
  • Shiyi Han,
  • Lianming Tong,
  • Peng Yu,
  • Yi Liu,
  • Hongyu Wu,
  • Shiwei Wu,
  • Jiang Xiao,
  • Ryuichi Shindou,
  • X. C. Xie,
  • Jian-Hao Chen

DOI
https://doi.org/10.1038/s41467-023-38172-7
Journal volume & issue
Vol. 14, no. 1
pp. 1 – 8

Abstract

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Abstract Anisotropy is a manifestation of lowered symmetry in material systems that have profound fundamental and technological implications. For van der Waals magnets, the two-dimensional (2D) nature greatly enhances the effect of in-plane anisotropy. However, electrical manipulation of such anisotropy as well as demonstration of possible applications remains elusive. In particular, in-situ electrical modulation of anisotropy in spin transport, vital for spintronics applications, has yet to be achieved. Here, we realized giant electrically tunable anisotropy in the transport of second harmonic thermal magnons (SHM) in van der Waals anti-ferromagnetic insulator CrPS4 with the application of modest gate current. Theoretical modeling found that 2D anisotropic spin Seebeck effect is the key to the electrical tunability. Making use of such large and tunable anisotropy, we demonstrated multi-bit read-only memories (ROMs) where information is inscribed by the anisotropy of magnon transport in CrPS4. Our result unveils the potential of anisotropic van der Waals magnons for information storage and processing.