Stabilization of A-site ordered perovskites and formation of spin-half antiferromagnetic lattice: CaCu3Ti4O12 and CaCu3Zr4O12

Abstract

A-site ordered perovskites, CaCu3B4O12, which are derivatives of conventional ABO3 perovskites, exhibit varying electronic and magnetic properties. With the objective of examining the role of Cu in this work, we have studied CaCu3Ti4O12 and CaCu3Zr4O12 and presented the cause of the crystallization of A-site ordered perovskite from conventional ABO3 perovskite and the underlying mechanism leading to the stabilization of non-trivial and experimentally estabilished G-type antiferromagnetic (G-AFM) ordering in these systems. The first-principles electronic structure calculations supplemented with phonon studies show that the formation of A-site ordered perovskite is driven by Jahn-Teller distortion of the CuO12 icosahedron. The crystal orbital Hamiltonian population analysis and magnetic exchange interactions estimated using spin dimer analysis infers that the nearest and next-nearest-neighbor interactions (J1 and J2) are direct and weakly ferromagnetic whereas the third-neighbor interaction (J3) is unusually strong and antiferromagnetic driven by indirect superexchange mechanism. The structural geometry reveals that stabilization of G-AFM requires J1 < 2J2, J1 < 2J3. The experimental and theoretical values of Neel Temperature agrees well for U ≈ 7 eV, highlighting the role of strong correlation. The magnetic ordering is found to be robust against pressure and strain.