Long Range Electronic Phase Separation in CaFeO

Overview

Journal Nat Commun

Specialty Biology

Date 2018 Aug 1

PMID 30061576

Citations 9

Authors

Ka H Hong

Angel M Arevalo-Lopez

James Cumby

Clemens Ritter

J Paul Attfield

Affiliations

Soon will be listed here.

Abstract

Incomplete transformations from ferromagnetic to charge ordered states in manganite perovskites lead to phase-separated microstructures showing colossal magnetoresistances. However, it is unclear whether electronic matter can show spontaneous separation into multiple phases distinct from the high temperature state. Here we show that paramagnetic CaFeO undergoes separation into two phases with different electronic and spin orders below their joint magnetic transition at 302 K. One phase is charge, orbital and trimeron ordered similar to the ground state of magnetite, FeO, while the other has Fe/Fecharge averaging. Lattice symmetry is unchanged but differing strains from the electronic orders probably drive the phase separation. Complex low symmetry materials like CaFeO where charge can be redistributed between distinct cation sites offer possibilities for the generation and control of electronic phase separated nanostructures.

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