Non-collinear 2k antiferromagnetism in the Zintl semiconductor Eu5In2Sb6
Abstract
Eu5In2Sb6 is an orthorhombic non-symmorphic small band gap semiconductor with three distinct Eu2+ sites and two low-temperature magnetic phase transitions. The material displays one of the greatest (negative) magnetoresistances of known stoichiometric antiferromagnets and belongs to a family of Zintl materials that may host an axion insulator. Using single crystal neutron diffraction, we show that the TN1=14~K second-order phase transition is associated with long-range antiferromagnetic order within the chemical unit cell ( k1 = (000) ). Upon cooling below TN1, the relative sublattice magnetizations of this structure vary until a second-order phase transition at TN2=7~K that doubles the unit cell along the c axis ( k2 = (0012) ). We show the anisotropic susceptibility and our magnetic neutron diffraction data are consistent with magnetic structures described by the 3 irreducible representation with the staggered magnetization of the k1 and k2 components polarized along the b and a axis, respectively. As the k2 component develops, the amplitude of the k1 component is reduced, which indicates a 2k non-collinear magnetic structure. Density functional theory is used to calculate the energies of these magnetic structures and to show the k1 phase is a metal so TN1 is a rare example of a unit-cell-preserving second-order phase transition from a paramagnetic semiconductor to an antiferromagnetic metal. DFT indicates the transition at TN2 to a doubled unit cell reduces the carrier density of the metal, which is consistent with resistivity data.
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