The super-super exchange mechanism in iron-based antiperovskite chalco-halides

Abstract

By using the first-principles electronic structure calculations, we have systematically studied the magnetism in three recently synthesized iron-based antiperovskite chalco-halides: Ba3(FeS4)Cl, Ba3(FeS4)Br, and Ba3(FeSe4)Br. These compounds consist of edge-sharing BaQ6 (Q=Cl or Br) octahedra intercalated with isolated FeX4 (X=S or Se) tetrahedra. We find that even though the shortest distances between the nearest-neighboring Fe atoms in these three compounds already exceed 6 , much larger than the bond length of a chemical bonding, they all remarkably show antiferromagnetic (AFM) coupling along b axis with very weak spin-spin correlation along a axis. Our study shows that the mechanism underlying this novel AFM coupling is such a new type of exchange interaction between the nearest-neighboring Fe-based super-moments mediated by Ba cations, which we call the super-super exchange interaction, in which each magnetic Fe atom partially polarizes its four nearest-neighboring X atoms to form a super-moment through p-d orbital hybridization and the X atoms in neighboring FeX4 tetrahedra along b axis antiferromagnetically couple with each others through the intermediate Ba cations. Different from the conventional superexchange, here it is cations rather than anions that mediate two neighboring super-moments. According to the calculated strength of the AFM coupling, we predict that among these compounds the highest AFM phase transition temperature TN may reach 110 K in Ba3(FeSe4)Br, in comparison with the observed TNs of 84 K in Ba3(FeS4)Br and 95 K in Ba3(FeS4)Cl.