Particle size dependence of magnetization and phase transition near T_N in multiferroic BiFeO3

TL;DR

This study investigates how particle size influences the magnetic and phase transition properties of multiferroic BiFeO3 near its Néel temperature, revealing size-dependent changes in transition sharpness and magnetic behavior.

Contribution

It provides a comprehensive analysis of the effects of particle size on phase transition characteristics and magnetic properties in BiFeO3, highlighting the emergence of ferromagnetism at nanoscale.

Findings

Bulk BiFeO3 shows sharp and broad features at T_N in calorimetry.

Nanoscale BiFeO3 exhibits only broad features with increased metastability.

Finite coercivity and potential ferromagnetism are observed at nanoscale.

Abstract

We report results of a comprehensive study of the phase transition at T_N (~643 K) as a function of particle size in multiferroic BiFeO3 system. We employed electrical, thermal, and temperature dependent X-ray diffraction (XRD) studies in order to characterize the transition in a host of samples. We also carried out detailed magnetic measurements over a temperature regime 2-300 K under a magnetic field 100-10000 Oe both on bulk and nano-crystalline systems. While in the bulk system a sharp endothermic peak at T_N together with a broad feature, ranging over nearly ~150 K (Delta_T), could be observed in calorimetry, the nanoscale systems exhibit only the broad feature. The characteristic dielectric anomaly, expected at T_N, is found to occur both at T_O and T_N across Delta_T in the bulk sample. The Maxwell-Wagner component due to interfaces between heterogenous regions with different conductivities is also present. The magnetic properties, measured at lower temperature, corroborate our observations in calorimetry. The metastability increases in the nanoscale BiFeO3 with divergence between zero-field cooled (ZFC) and field cooled (FC) magnetization below ~100 K and faster magnetic relaxation. Interestingly, in nanoscale BiFeO3, one also observes finite coercivity at lower temperature which points out that suitable design of particle size and shape may induce ferromagnetism. The inhomogeneous distribution of Bi/Fe-ions and/or oxygen non-stoichiometry seems to be giving rise to broad features in thermal, magnetic as well as in electrical responses.