Communications Materials (Aug 2024)

Static magnetic order with strong quantum fluctuations in spin-1/2 honeycomb magnet Na2Co2TeO6

  • Jinlong Jiao,
  • Xiyang Li,
  • Gaoting Lin,
  • Mingfang Shu,
  • Wei Xu,
  • Oksana Zaharko,
  • Toni Shiroka,
  • Tao Hong,
  • Alexander I. Kolesnikov,
  • Guochu Deng,
  • Sarah Dunsiger,
  • Meigan C. Aronson,
  • Haidong Zhou,
  • Xiaoqun Wang,
  • Tian Shang,
  • Jie Ma

DOI
https://doi.org/10.1038/s43246-024-00594-1
Journal volume & issue
Vol. 5, no. 1
pp. 1 – 7

Abstract

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Abstract Kitaev interactions, arising from the interplay of frustration and bond anisotropy, can lead to strong quantum fluctuations and, in an ideal case, to a quantum-spin-liquid state. However, in many nonideal materials, spurious non-Kitaev interactions typically promote a zigzag antiferromagnetic order in the d-orbital transition-metal compounds. Here, by combining neutron scattering with muon-spin rotation and relaxation techniques, we provide mechanism insights into the exotic properties of Na2Co2TeO6, a candidate material of the Kitaev model. Below T N, the zero-field muon-spin relaxation rate becomes almost constant (~0.45 μs−1). We attribute this temperature-independent relaxation rate to the strong quantum fluctuations, as well as to the frustrated Kitaev interactions. As the magnetic field increases, neutron scattering data indicate a broader spin-wave excitation at the K-point. Therefore, quantum fluctuations seem not only robust but are even enhanced by the applied magnetic field. Our findings provide valuable hints for understanding the onset of the quantum-spin-liquid state in Kitaev materials.