Evidence of discrete energy states and cluster-glass behavior in Sr$_{2-x}$La$_x$CoNbO$_6$

TL;DR

This study investigates the magnetic interactions and energy states in Sr$_{2-x}$La$_x$CoNbO$_6$ double perovskites, revealing discrete energy states, high-spin Co$^{3+}$ ions, and cluster-glass behavior, with evolution across different La doping levels.

Contribution

It provides new insights into the low-temperature magnetic states, energy level structure, and phase transitions in Sr$_{2-x}$La$_x$CoNbO$_6$, highlighting the presence of discrete energy states and cluster-glass behavior.

Findings

Schottky anomaly shifts with x and magnetic field

Presence of high-spin Co$^{3+}$ ions near low-spin state

Cluster-glass behavior in low x samples

Abstract

We report the detailed analysis of specific heat [C$_{\rm P}$(T)] and ac-susceptibility for magnetically frustrated Sr$_{2-x}$La$_x$CoNbO$_6$ ($x=$ 0--1) double perovskites to understand low temperature complex magnetic interactions and their evolution with $x$. Interestingly, the observed Schottky anomaly in the $x\leqslant$ 0.4 samples shifts gradually towards higher temperature with magnetic field as well as $x$, and the analysis reveal the persistence of the discrete energy states in these samples resulting from the spin-orbit coupling and octahedral distortion. Moreover, the extracted values of Land\'e g--factor indicate the existence of high-spin state Co$^{3+}$ ions close to non-magnetic low-spin state. The specific heat data show the $\lambda$-type anomaly for the $x\geqslant$ 0.6 samples due to evolution of the long range antiferromagnetic ordering. Our analysis of low temperature C$_{\rm P}$(T) data for the $x\geqslant$ 0.6 samples demonstrate the 3D isotropic Heisenberg antiferromagnetic (AFM) interactions and the temperature induced second order AFM--paramagnetic phase transition. More interestingly, we demonstrate the presence of the free Co$^{2+}$ like Kramers doublet ground state in the $x =$1 sample. Further, the ac susceptibility and time evolution of the magnetization data reveal the low temperature cluster-glass like behavior in the $x=$ 0--0.4 samples, where spin-spin correlation strength decreases with $x$.