Scaling and Data Collapse from Local Moments in Frustrated Disordered Quantum Spin Systems

Overview

Journal Nat Commun

Specialty Biology

Date 2018 Oct 24

PMID 30349043

Citations 9

Authors

Itamar Kimchi

John P Sheckelton

Tyrel M McQueen

Patrick A Lee

Affiliations

Soon will be listed here.

Abstract

Recently measurements on various spin-1/2 quantum magnets such as HLiIrO, LiZnMoO, ZnCu(OH)Cl and 1T-TaS-all described by magnetic frustration and quenched disorder but with no other common relation-nevertheless showed apparently universal scaling features at low temperature. In particular the heat capacity C[H, T] in temperature T and magnetic field H exhibits T/H data collapse reminiscent of scaling near a critical point. Here we propose a theory for this scaling collapse based on an emergent random-singlet regime extended to include spin-orbit coupling and antisymmetric Dzyaloshinskii-Moriya (DM) interactions. We derive the scaling C[H, T]/T ~ HF[T/H] with F[x] = x at small x, with q ∈ {0, 1, 2} an integer exponent whose value depends on spatial symmetries. The agreement with experiments indicates that a fraction of spins form random valence bonds and that these are surrounded by a quantum paramagnetic phase. We also discuss distinct scaling for magnetization with a q-dependent subdominant term enforced by Maxwell's relations.

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