Magnetothermopower in Nd1-xEuxNiO3 compounds

TL;DR

This study investigates the magnetothermopower and related properties of Nd1-xEuxNiO3 compounds, revealing complex charge carrier behavior, phase coexistence, and magnetic field effects on thermoelectric performance.

Contribution

It provides new insights into the magnetothermopower effects and phase coexistence in Nd1-xEuxNiO3, highlighting the influence of magnetic fields on thermoelectric properties.

Findings

Metal-insulator transition occurs between 200-325 K.

Magnetothermopower effect enhances thermopower by ~25% under magnetic field.

Coexistence of ordered and disordered phases below TN.

Abstract

We have measured magnetization M(T,H), electrical resistivity ro(T,H), thermal conductivity k(T,H), and thermopower S(T,H) of polycrystalline samples of Nd1-xEuxNiO3; 0 <= x <= 0.35; as a function of temperature and external magnetic field. The data indicate a metal-insulator transition (MI) in a wide range of temperature (200 < TMI < 325 K). The magnetic susceptibility X(T) data, after the subtraction of the rare-earth contribution, exhibit a Curie-Weiss like behavior at temperatures above TMI. Although a clear antiferromagnetic AF transition of the Ni sub-lattice is observed at TN <= TMI, X(T) still increases down to 5 K, suggesting a heterogeneous ground state. The thermal conductivity of the NdNiO3 compound is not affected by an external magnetic field of 90 kOe in a wide range of temperature, and its temperature dependence below 15 K is approximately quadratic, strongly suggesting the presence of disorder. S(T) is negative above TMI and varies linearly with temperature. Below TMI, S(T) does not follow the expected behavior of insulating compounds. There is a minimum close to 120 K, and S(T) changes its sign at T ~ 30 K, indicating a competition between two types of charge carriers. A pronounced peak in S(T) at TS ~ 20 K does not follow the expected phonon-drag temperature dependence either above or below TS and the peak remains unaltered under magnetic fields up to 90 kOe. However, its magnitude is enhanced by ~ 25 % with applied magnetic field, exhibiting a clear magnetothermopower effect. The combined results indicate a coexistence of ordered and disordered phases below TN and that an applied magnetic field is suitable for enhancing the thermoelectric properties close to TS.