Colossal magnetoresistance in EuZn2P2 and its electronic and magnetic structure

Abstract

We investigate single crystals of the trigonal antiferromagnet EuZn2P2 (P3m1) by means of electrical transport, magnetization measurements, X-ray magnetic scattering, optical reflectivity, angle-resolved photoemission spectroscopy (ARPES) and ab-initio band structure calculations (DFT+U). We find that the electrical resistivity of EuZn2P2 increases strongly upon cooling and can be suppressed in magnetic fields by several orders of magnitude (CMR effect). Resonant magnetic scattering reveals a magnetic ordering vector of q = (0\, 0\, 12), corresponding to an A-type antiferromagnetic (AFM) order, below T N = 23.7\, K. We find that the moments are canted out of the a-a plane by an angle of about 40 10 degrees and aligned along the [100] in the a-a plane. We observe nearly isotropic magnetization behavior for low fields and low temperatures which is consistent with the magnetic scattering results. The magnetization measurements show a deviation from the Curie-Weiss behavior below ≈ 150\, K, the temperature below which also the field dependence of the material's resistivity starts to increase. An analysis of the infrared reflectivity spectrum at T=295\, K allows us to resolve the main phonon bands and intra-/interband transitions, and estimate indirect and direct band gaps of Eiopt=0.09\,eV and Edopt=0.33\,eV, respectively, which are in good agreement with the theoretically predicted ones. The experimental band structure obtained by ARPES is nearly T-independent above and below T N. The comparison of the theoretical and experimental data shows a weak intermixing of the Eu 4f states close to the point with the bands formed by the phosphorous 3p orbitals leading to an induction of a small magnetic moment at the P sites.