Low-field magnetic anomalies in single crystals of the A-type square-lattice antiferromagnet EuGa4

Abstract

The body-centered-tetragonal antiferromagnet EuGa4 was recently identified as a Weyl nodal-line semimetal that exhibits the topological Hall effect below its reported antiferromagnetic (AFM) ordering temperature T N= 15-16.5 K which we find to be T N = 16.4(2) K. The Eu+2 ions are located at the corners and body center of the unit cell. EuGa4 exhibits A-type AFM order below T N, where the Eu2+ spin-7/2 moments are ferromagnetically aligned in the ab plane with the Eu moments in adjacent Eu planes along the c axis aligned antiferromagnetically. Low-field magnetization versus field M(Hab) data at T=2 K with the field aligned in the ab plane are reported that exhibit anomalous positive curvature up to a critical field Hc1 at which a second-order transition occurs with Hc1≈ 0.85 kOe for H [1,1,0] and ≈ 4.8 kOe for H [1,0,0]. For larger fields, a linear behavior Mab = (T N)Hab is followed until the previously-reported critical field H cab = 71 kOe is reached at which all moments become aligned with the applied field. A theory is formulated for T=0 K that fits the observed M(Hab) behavior at T=2 K well, where domains of A-type AFM order with fourfold rotational symmetry occur in the AFM state in zero field. The moments in the four domains reorient to become almost perpendicular to Hab at Hc1, followed by increasing canting of all moments toward the field with increasing field up to H cab. A first-order transition in M(Hab) at Hab=H c1 is predicted by the theory for T=0 K when Hab is at a small angle from the [1,0,0] or [1,1,0] directions.