Multiferroicity in the Presence of Exchange Bias: The Case of Spinel CoMn2O4

TL;DR

This study synthesizes and characterizes CoMn2O4 spinel, revealing magnetic transitions, exchange bias, and dielectric-magnetic correlations, but no intrinsic ferroelectricity.

Contribution

It provides detailed magnetic, dielectric, and structural analysis of CoMn2O4, highlighting exchange bias and magnetodielectric effects without intrinsic ferroelectricity.

Findings

Two magnetic transitions at 186 K and 86 K.

Observation of exchange bias below 86 K.

Dielectric permittivity correlates with magnetization, but no intrinsic ferroelectricity.

Abstract

Ferrimagnetic spinel materials of formula AB2X4, where A and B are transition metals and X is oxygen or sulphur, hold promise for the realization of multiferroic characteristics. In this work, we report synthesis of spinel CoMn2O4 and explore its magnetic, dielectric, and ferroelectric aspects and their correlations. Polycrystalline CoMn2O4 was synthesized by using the conventional solid-state method. The X-ray diffraction (XRD) and Raman spectroscopy confirmed the phase purity of the synthesized compound. The crystal structure was identified with tetragonal symmetry (I41/amd space group). DC magnetization measurements indicate two magnetic transitions: one at temperature T1 ~ 186 K, followed by another Yafet-Kittel (YK) ferrimagnetic transition at T2 ~ 86 K. A frequency independent anomaly in the temperature dependent dielectric permittivity is observed near the low magnetic ordering temperature (T2). This reflects the possibility of the correlation between lattice dynamics and spin ordering in spinel CoMn2O4. A substantial exchange bias was also observed below T2 ~ 86 K. The change in dielectric permittivity in the presence of applied magnetic field follows the square of the magnetization dependence, which is consistent with Ginzburg-Landau theory. However, the detailed pyroelectric current measurements reveal the absence of intrinsic ferroelectric order.