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@ARTICLE{Wu:911784,
      author       = {Wu, Jiangtao and Li, Jianshu and Zhang, Zheng and Liu,
                      Changle and Gao, Yong Hao and Feng, Erxi and Deng, Guochu
                      and Ren, Qingyong and Wang, Zhe and Chen, Rui and Embs, Jan
                      and Zhu, Fengfeng and Huang, Qing and Xiang, Ziji and Chen,
                      Lu and Wu, Yan and Choi, E. S. and Qu, Zhe and Li, Lu and
                      Wang, Junfeng and Zhou, Haidong and Su, Yixi and Wang,
                      Xiaoqun and Chen, Gang and Zhang, Qingming and Ma, Jie},
      title        = {{M}agnetic field effects on the quantum spin liquid
                      behaviors of {N}a{Y}b{S}$_2$},
      journal      = {Quantum frontiers},
      volume       = {1},
      number       = {1},
      issn         = {2731-6106},
      address      = {Singapore},
      publisher    = {Springer Nature Singapore},
      reportid     = {FZJ-2022-05035},
      pages        = {13},
      year         = {2022},
      abstract     = {Spin-orbit coupling is an important ingredient to regulate
                      the many-body physics, especially for many spin liquid
                      candidate materials such as rare-earth magnets and Kitaev
                      materials. The rare-earth chalcogenides (Ch = O, S, Se) is a
                      congenital frustrating system to exhibit the intrinsic
                      landmark of spin liquid by eliminating both the site
                      disorders between and ions with the big ionic size
                      difference and the Dzyaloshinskii-Moriya interaction with
                      the perfect triangular lattice of the ions. The temperature
                      versus magnetic-field phase diagram is established by the
                      magnetization, specific heat, and neutron-scattering
                      measurements. Notably, the neutron diffraction spectra and
                      the magnetization curve might provide microscopic evidence
                      for a series of spin configuration for in-plane fields,
                      which include the disordered spin liquid state, 120°
                      antiferromagnet, and one-half magnetization state.
                      Furthermore, the ground state is suggested to be a gapless
                      spin liquid from inelastic neutron scattering, and the
                      magnetic field adjusts the spin orbit coupling. Therefore,
                      the strong spin-orbit coupling in the frustrated quantum
                      magnet substantially enriches low-energy spin physics. This
                      rare-earth family could offer a good platform for exploring
                      the quantum spin liquid ground state and quantum magnetic
                      transitions.},
      cin          = {JCNS-FRM-II / MLZ / JCNS-2 / JCNS-4},
      cid          = {I:(DE-Juel1)JCNS-FRM-II-20110218 / I:(DE-588b)4597118-3 /
                      I:(DE-Juel1)JCNS-2-20110106 / I:(DE-Juel1)JCNS-4-20201012},
      pnm          = {6G4 - Jülich Centre for Neutron Research (JCNS) (FZJ)
                      (POF4-6G4) / 632 - Materials – Quantum, Complex and
                      Functional Materials (POF4-632)},
      pid          = {G:(DE-HGF)POF4-6G4 / G:(DE-HGF)POF4-632},
      experiment   = {EXP:(DE-MLZ)External-20140101},
      typ          = {PUB:(DE-HGF)16},
      doi          = {10.1007/s44214-022-00011-z},
      url          = {https://juser.fz-juelich.de/record/911784},
}