Multi-q Origin of Unconventional Surface States in a High-Symmetry Lattice
Date
2022
Authors
Wang, Lin-Lin
Ahn, J.
Slager, R.-J.
Kushnirenko, Yevhen
Ueland, Benjamin G.
Sapkota, Aashish
Schrunk, Benjamin
Kuthanazhi, Brinda
McQueeney, Robert J.
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Publisher
arXiv
Abstract
A variety of complex magnetic structures in a high-symmetry lattice can arise from a superposition of well-defined magnetic wave vectors. These "multi-q" structures have garnered much attention because their non-collinear magnetic moment patterns can generate interesting real-space spin textures such as skyrmions. However, the role multi-q structures play in the topology of electronic bands in momentum space has remained rather elusive. In this work, we show that 2q and 3q antiferromagnetic structures in a cubic lattice with band inversion, such as NdBi, can induce unconventional surface state pairs in the band-folding bulk gap. Our density functional theory calculations match well with the recent experimental observation of unconventional surface state hole Fermi arcs and electron pockets below the magnetic transition temperature, which can not be explained with its previously reported single-q structure. We further show that these multi-q structures have also 3D Dirac and Weyl nodal features. Our work reveals the special role that multi-q structures can play in the development of new quantum states and suggests that NdBi is a multi-q antiferromagnet.
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Preprint
Comments
This is a pre-print of the article Wang, L-L., J. Ahn, R-J. Slager, Y. Kushnirenko, B. G. Ueland, A. Sapkota, B. Schrunk et al. "Multi-q Origin of Unconventional Surface States in a High-Symmetry Lattice." arXiv preprint arXiv:2203.12541 (2022).
DOI: 10.48550/arXiv.2203.12541.
Attribution 4.0 International (CC BY 4.0).
Copyright 2022 The Authors.
Posted with permission.