@article{Song2023, 
author = {Yang Song and Wen-Han Dong and Kuan-Rong Hao and Shixuan Du and Lizhi Zhang},
title = {Designing topological and correlated 2D magnetic states via superatomic lattice constructions of zirconium dichloride},
year = {2023},
journal = {Nano Research},
volume = {16},
number = {12},
pages = {13509-13515},
keywords = {kagome lattice, topological state, Chern insulator, zirconium dichloride, superatomic lattice, Dirac Mott insulator},
url = {https://www.sciopen.com/article/10.1007/s12274-023-6066-3},
doi = {10.1007/s12274-023-6066-3},
abstract = {Magnetic materials could realize the intriguing quantum anomalous Hall effect and metal-to-insulator transition when combined with band topology or electronic correlation, which have broad prospects in quantum information, spintronics, and valleytronics. Here, we propose the approach of designing novel two-dimensional (2D) magnetic states via d-orbital-based superatomic lattices. Specifically, we chose triangular zirconium dichloride disks as superatoms to construct the honeycomb superatomic lattices. Using first-principles calculations, we identified a series of 2D magnetic states with varying sizes of superatoms. We found the non-uniform stoichiometries and geometric effect of superatomic lattice give rise to spin-polarized charges arranged in different magnetic configurations, containing ferromagnetic coloring triangles, antiferromagnetic honeycomb, and ferromagnetic kagome lattices. Attractively, these magnetic states are endowed with nontrivial band topology or strong correlation, forming an ideal Chern insulator or antiferromagnetic Dirac Mott insulator. Our work not only reveals the potential of d-orbital-based superatoms for generating unusual magnetic configurations, but also supplies a new avenue for material engineering at the nanoscale.}
}