Decisive Influence of Cation Size on the Magnetic Groundstate and Non-Fermi Liquid Behavior of ARuO3 (A = Ca, Sr)

TL;DR

This study investigates how the size of the A-site cation in ARuO3 compounds influences their magnetic ground states and non-Fermi-liquid behavior, revealing that CaRuO3 exhibits quantum criticality unlike SrRuO3.

Contribution

It demonstrates the decisive role of cation size in determining magnetic and electronic properties, highlighting CaRuO3 as a non-Fermi-liquid near a quantum critical point.

Findings

CaRuO3 shows non-Fermi-liquid behavior with T-log T heat capacity.

Magnetic susceptibility diverges as T^-x with 1/2 < x < 1.

Electrical resistivity follows a T^{3/2} dependence.

Abstract

We report calorimetric, magnetic and electric transport properties of single-crystal CaRuO3 and SrRuO3 as a function of temperature T and applied magnetic field B. We find that CaRuO3 is a non-Fermi-liquid metal near a magnetic instability, as characterized by the following properties: (1) the heat capacity C(T,B) ~ -T log T is readily enhanced in low applied fields, and exhibits a Schottky peak at 2.3 K that exhibits field dependence when T is reduced; (2) the magnetic susceptibility diverges as T^-x at low temperatures with 1/2 < x < 1, depending on the applied field; and (3) the electrical resistivity exhibits a T3/2 dependence over the range 1.7 < T < 24 K. No Shubnikov-de Haas oscillations are discerned at T = 0.65 K for applied fields up to 45 T. These properties, which sharply contrast those of the itinerant ferromagnet SrRuO3, indicate CaRuO3 is a rare example of a stoichiometric oxide compound that exhibits non-Fermi-liquid behavior near a quantum critical point.