The effect of disorder on quantum phase transition in the double layered ruthenates (Sr1-xCax)3Ru2O7

TL;DR

This study investigates how disorder influences quantum phase transitions in (Sr1-xCax)3Ru2O7, revealing anomalous power-law behaviors and a scaling law near the spin freezing transition, with implications for understanding magnetic states in disordered quantum materials.

Contribution

The paper presents a detailed scaling analysis of magnetization and specific heat, uncovering a phenomenological scaling law and disorder effects on quantum phase transitions in (Sr1-xCax)3Ru2O7.

Findings

Power-law singularities in magnetization and specific heat above T_f.

A scaling law M(H,T)  H^ f(H/T^) observed.

Breakdown of scaling near critical concentration x=0.1.

Abstract

(Sr1-xCax)3Ru2O7 is characterized by complex magnetic states, spanning from a long-range antiferromagnetically ordered state over an unusual heavy-mass nearly ferromagnetic (NFM) state to an itinerant metamagnetic (IMM) state. The NFM state, which occurs in the 0.4 > x > 0.08 composition range, freezes into a cluster-spin-glass (CSG) phase at low temperatures [Z. Qu et al., Phys. Rev. B 78, 180407(R) (2008)]. In this article, we present the scaling analyses of magnetization and the specific heat for (Sr1-xCax)3Ru2O7 in the 0.4 > x > 0.08 composition range. We find that in a temperature region immediately above the spin freezing temperature T$_f$, the isothermal magnetization M(H) and the temperature dependence of electronic specific heat C_e(T) exhibit anomalous power-law singularities; both quantities are controlled by a single exponent. The temperature dependence of magnetization M(T) also displays a power-law behavior, but its exponent differs remarkably from that derived from M(H) and C_e(T). Our analyses further reveal that the magnetization data M(H,T) obey a phenomenological scaling law of M(H,T) \propto H^\alpha f(H/T^\delta) in a temperature region between the spin freezing temperature T_f and the scaling temperature T_scaling. T_scaling systematically decreases with the decease of Ca content. This scaling law breaks down near the critical concentration x = 0.1 where a CSG-to-IMM phase transition occurs. We discussed these behaviors in term of the effect of disorder on the quantum phase transition.