Anomalous Hall Resistivity of TbBaCo2O5.53 with Non-trivial Magnetic Structure

TL;DR

This study explores the anomalous Hall resistivity in TbBaCo2O5.53, revealing how non-trivial magnetic structures influence transport properties across magnetic phase transitions.

Contribution

It provides new insights into the relationship between non-trivial magnetic structures and anomalous Hall effects in oxygen-deficient perovskites.

Findings

Unusual magnetic field dependence of Hall resistivity observed between 200 K and T1.

Analysis of Hall coefficients reveals temperature-dependent behavior linked to magnetic phases.

Non-trivial magnetic structures are likely responsible for the anomalous Hall behavior.

Abstract

To investigate the Hall resistivity rH of systems with non-trivial spin structures, transport and magnetic properties of the oxygen deficient perovskite system TbBaCo2O5.53 with non-trivial magnetic structures have been adopted. As has been already known, the system exhibits, with decreasing temperature T, a transition to a ferromagnetic (FM) phase with non-collinear magnetic structure at TC 280 K in zero magnetic field and with further decreasing T, the spontaneous magnetization begins to decrease at T1~260 K and becomes zero at TN 245 K, where an antiferromagnetic (AFM) phase with non-collinear magnetic structure is realized. The metamagnetic behavior is induced by the relatively small magnetic field H (< 5 T) in the T region between ~200 K and T1. In this T region, unusual H dependence of rH has been observed. By analyzing the observed rH and magnetization M, the H dependence of the anomalous Hall coefficients Rs has been obtained at various fixed temperatures. Based on the magnetic structure reported previously by our group, the possible relevance of the non-trivial magnetic structure to the observed unusual behavior of rH is pointed out.