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@ARTICLE{Li:1023086,
      author       = {Li, Zhidong and Zhang, Ruifu and Shan, Jun and Alahmed,
                      Laith and Xu, Ailing and Chen, Yuanping and Yuan, Jiaren and
                      Cheng, Xiaomin and Miao, Xiangshui and Wen, Jiajia and
                      Mokrousov, Yuriy and Lee, Young S. and Zhang, Lichuan and
                      Li, Peng},
      title        = {{E}lectrostatic {G}ating of {S}pin {D}ynamics of a
                      {Q}uasi-2{D} {K}agome {M}agnet},
      journal      = {Nano letters},
      volume       = {24},
      number       = {7},
      issn         = {1530-6984},
      address      = {Washington, DC},
      publisher    = {ACS Publ.},
      reportid     = {FZJ-2024-01658},
      pages        = {2415–2420},
      year         = {2024},
      abstract     = {Electrostatic gating has emerged as a powerful technique
                      for tailoring the magnetic properties of two-dimensional
                      (2D) magnets, offering exciting prospects including
                      enhancement of magnetic anisotropy, boosting Curie
                      temperature, and strengthening exchange coupling effects.
                      Here, we focus on electrical control of the ferromagnetic
                      resonance of the quasi-2D Kagome magnet Cu(1,3-bdc). By
                      harnessing an electrostatic field through ionic liquid
                      gating, significant shifts are observed in the ferromagnetic
                      resonance field in both out-of-plane and in-plane
                      measurements. Moreover, the effective magnetization and
                      gyromagnetic ratios display voltage-dependent variations. A
                      closer examination reveals that the voltage-induced changes
                      can modulate magnetocrystalline anisotropy by several
                      hundred gauss, while the impact on orbital magnetization
                      remains relatively subtle. Density functional theory (DFT)
                      calculations reveal varying d-orbital hybridizations at
                      different voltages. This research unveils intricate physics
                      within the Kagome lattice magnet and further underscores the
                      potential of electrostatic manipulation in steering
                      magnetism with promising implications for the development of
                      spintronic devices.},
      cin          = {PGI-1},
      ddc          = {660},
      cid          = {I:(DE-Juel1)PGI-1-20110106},
      pnm          = {5211 - Topological Matter (POF4-521)},
      pid          = {G:(DE-HGF)POF4-5211},
      typ          = {PUB:(DE-HGF)16},
      pubmed       = {38323579},
      UT           = {WOS:001173919100001},
      doi          = {10.1021/acs.nanolett.4c00034},
      url          = {https://juser.fz-juelich.de/record/1023086},
}