Theory of Manganites Exhibiting Colossal Magnetoresistance
Abstract
The electronic properties of many transition metal oxide systems require new ideas concerning the behaviour of electrons in solids for their explanation. A recent example, subsequent to that of cuprate superconductors, is of rare earth manganites doped with alkaline earths, namely Re1-xAx MnO3, which exhibit colossal magnetoresistance, metal insulator transition and many other poorly understood phenomena. Here we show that the strong Jahn Teller coupling between the twofold degenerate (dx2 -y2 and d3z2 -r2) eg orbitals of Mn and lattice modes of vibration (of the oxygen octahedra surrounding the Mn ions) dynamically reorganizes the former into a set of states (which we label ) which are localized with large local lattice distortion and exponentially small intersite overlap, and another set (labelled b) which form a broad band. This hitherto unsuspected but microscopically inevitable coexistence of radically different and b states, and their relative energies and occupation as influenced by doping x, temperature T, local Coulomb repulsion U etc., underlies the unique effects seen in manganites. We present results from strong correlation calculations using the dynamical mean-field theory which accord with a variety of observations in the orbital liquid regime (say, for 0.2< x < 0.5).We outline extensions to include intersite coherence and spatial correlations/long range order.
Turn this paper into a full lesson
ArcXiv compiles a staged curriculum from this paper: 8-12 lessons across beginner → advanced, synthesised section guides, visuals, flashcards, a quiz, exercises, and on-demand deep dives per section. Grounded in the abstract, never invented.