Intrinsic electronic phase separation and competition between $G$-type, $C$-type and $CE$-type charge and orbital ordering modes in Hg$_{1-x}$Na$_x$Mn$_3$Mn$_4$O$_{12}$

TL;DR

This study investigates the charge and orbital order behavior in hole-doped Hg$_{1-x}$Na$_x$Mn$_3$Mn$_4$O$_{12}$ manganites, revealing a rare polar G-type ordered ground state and phase separation linked to colossal magnetoresistance.

Contribution

It uncovers the existence of a polar G-type charge and orbital ordered ground state in Hg$_{1-x}$Na$_x$Mn$_3$Mn$_4$O$_{12}$ and explains its formation mechanism, expanding understanding of manganite phases.

Findings

Identification of a polar G-type charge and orbital ordered ground state.

Observation of electronic phase separation at critical doping levels.

Linking charge transfer processes to ferroelectric polarization mechanism.

Abstract

The novel series of hole-doped quadruple manganite perovskites Hg$_{1-x}$Na$_x$Mn$_3$Mn$_4$O$_{12}$ (HNMO) has been synthesized and its charge and orbital order behavior investigated through high-resolution synchrotron powder x-ray diffraction techniques. Through careful Rietveld refinements of structural models $via$ symmetry-motivated approaches, we show that the ground state of HNMO compositions adopts a polar $G$-type charge and orbital ordered state, which is rare in manganite perovskites, and is robust as a sole phase up to a critical doping level. Upon this critical doping, coincident with that in which colossal magnetoresistance (CMR) is maximal in canonical manganite perovskites, electronic phase separation occurs between $G$-type and orbital order with charge disorder-type states. The latter state has recently been identified in Ca$_{1-x}$Na$_x$Mn$_3$Mn$_4$O$_{12}$ perovskites, and proposed to be the competing insulating state from which CMR phenomena emerges. We show the mechanism for the formation of the $G$-type state is due to charge transfer processes which may occur through a coupling of distortions involving structural and charge and orbital degrees of freedom, ultimately driving the polar ground state through an improper-like ferroelectric polarization mechanism. These results will act as an important recipe for designing novel ferroelectric-active materials, in addition to expanding the richness of charge and orbital ordered states in manganite perovskites.