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arxiv: 2203.11848 · v1 · pith:WXWPKYCO · submitted 2022-03-22 · cond-mat.mtrl-sci · cond-mat.mes-hall· cond-mat.other

Electronic structure and open-orbit Fermi surface topology in isostructural semimetals NbAs₂ and W₂As₃ with extremely large magnetoresistance

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classification cond-mat.mtrl-sci cond-mat.mes-hallcond-mat.other
keywords open-orbittopologyelectronicextremelyfermigroupisostructurallarge
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In transition-metal dipnictides $TmPn_2$ ($Tm$ = Ta, Nb; $Pn$ = P, As, Sb), the origin of extremely large magnetoresistance (XMR) is yet to be studied by the direct visualization of the experimental band structures. Here, using angle-resolved photoemission spectroscopy, we map out the three-dimensional electronic structure of NbAs$_2$. The open-orbit topology contributes to a non-negligible part of the Fermi surfaces (FSs), like that of the isostructural compound MoAs$_2$, where the open FS is proposed to likely explain the origin of XMR. We further demonstrate the observation of open characters in the overall FSs of W$_2$As$_3$, which is also a XMR semimetal with the same space group of $C$12/$m$1 as $TmPn_2$ family and MoAs$_2$. Our results suggest that the open-orbit FS topology may be a shared feature between XMR materials with the space group of $C$12/$m$1, and thus could possibly play a role in determining the corresponding XMR effect together with the electron-hole compensation.

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