Interplay of magnetic ordering and charge transport in a distorted ScAl3C3-type GdZn3As3

Abstract

We present the synthesis and characterization of GdZn3As3, a previously unreported variant of the RM3X3 family (R = lanthanides; M = Zn, Cd; X = P, As), prepared in both single-crystal and polycrystalline forms. Unlike other RM3X3 compounds that crystallize in undistorted hexagonal structures, GdZn3As3 adopts a distorted ScAl3C3-type orthorhombic structure with Cmcm space group. Magnetic measurements demonstrate that GdZn3As3 undergoes a ferromagnetic transition at the Curie temperature (TC) of 6.3~K, which is unique among known RM3X3 materials. This magnetic transition is further confirmed by specific heat and electrical resistivity measurements. GdZn3As3 displays metallic behavior with a pronounced resistivity peak near TC, which is strongly suppressed by magnetic fields, leading to significant negative magnetoresistance. Hall effect measurements reveal a low carrier density and a clear nonlinear anomalous Hall effect in GdZn3As3. Furthermore, both specific heat and resistivity data suggest the presence of additional magnetic transition(s) below TC, requiring further investigation. These results demonstrate that GdZn3As3 possesses distinct structural, magnetic, and electronic transport properties within the RM3X3 family, establishing it as an exceptional platform for investigating competing magnetic interactions in low-carrier-density rare-earth triangular-lattice systems.