Magnetoresistance and Kondo effect in the nodal-line semimetal VAs2

Abstract

We performed calculations of the electronic band structure and the Fermi surface as well as measured the longitudinal resistivity xx(T,H), Hall resistivity xy(T,H), and magnetic susceptibility as a function of temperature and various magnetic fields for VAs2 with a monoclinic crystal structure. The band structure calculations show that VAs2 is a nodal-line semimetal when spin-orbit coupling is ignored. The emergence of a minimum at around 11 K in xx(T) measured at H = 0 demonstrates that an additional magnetic impurity (V4+, S = 1/2) occurs in VAs2 single crystals, evidenced by both the fitting of xx(T) data and the susceptibility measurements. It was found that a large positive magnetoresistance (MR) reaching 649\% at 10 K and 9 T, its nearly quadratic field dependence, and a field-induced up-turn behavior of xx(T) emerge also in VAs2, although MR is not so large due to the existence of additional scattering compared with other topological nontrival/trival semimetals. The observed properties are attributed to a perfect charge-carrier compensation, which is evidenced by both calculations relying on the Fermi surface and the Hall resistivity measurements. These results indicate that the compounds containing V (3d3 4s2) element as a platform for studying the influence of magnetic impurities to the topological properties.