Spin versus Lattice Polaron: Prediction for Electron-Doped CaMnO3
Abstract
CaMnO3 is a simple bi-partite antiferromagnet(AF) which can be continuously electron-doped up to LaMnO3. Electrons enter the doubly degenerate Eg subshell with spins aligned to the S=3/2 core of Mn4+ (T2g3)$. We take the Hubbard and Hund energies to be effectively infinite. Our model Hamiltonian has two Eg orbitals per Mn atom, nearest neighbor hopping, nearest neighbor exchange coupling of the S=3/2 cores, and electron-phonon coupling of Mn orbitals to adjacent oxygen atoms. We solve this model for light doping. Electrons are confined in local ferromagnetic (FM) regions (spin polarons) where there proceeds an interesting competition between spin polarization (spin polarons) which enlarges the polaron, and lattice polarization (Jahn-Teller polarons) which makes it smaller. A symmetric 7-atom ferromagnetic cluster (Mn727+) is the stable result, with net spin S=2 relative to the undoped AF. The distorted oxygen positions around the electron are predicted. The model also predicts a critical doping xc=0.045 where the polaronic insulator becomes unstable relative to a FM metal.
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