Universal scaling at field-induced magnetic phase transitions

A. Dorneich; A. Oosawa; A. Oosawa; A.W. Sandvik; A.W. Sandvik; A.W. Sandvik; B. Normand; Ch. Rüegg; G. Chaboussant; H. Tanaka; M. Hasenbusch; M. Matsumoto; M. Mito; M.B. Stone; N. Cavadini; O.F. Syljuåsen; Omid Nohadani; S. Wessel; Stefan Wessel; Stephan Haas; T. Giamarchi; T. Kato; T. Nikuni; W. Shiramura

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Universal scaling at field-induced magnetic phase transitions

Authors: A. Dorneich
A. Oosawa
A. Oosawa
A.W. Sandvik
A.W. Sandvik
A.W. Sandvik
B. Normand
Ch. Rüegg
G. Chaboussant
H. Tanaka
M. Hasenbusch
M. Matsumoto
M. Mito
M.B. Stone
N. Cavadini
O.F. Syljuåsen
Omid Nohadani
S. Wessel
Stefan Wessel
Stephan Haas
T. Giamarchi
T. Kato
T. Nikuni
W. Shiramura
Publication date: 7 July 2003
Publisher: 'American Physical Society (APS)'
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Abstract

We study field-induced magnetic order in cubic lattices of dimers with antiferromagnetic Heisenberg interactions. The thermal critical exponents at the quantum phase transition from a spin liquid to a magnetically ordered phase are determined from Stochastic Series Expansion Quantum Monte Carlo simulations. These exponents are independent of the interdimer coupling ratios, and converge to the value obtained by considering the transition as a Bose-Einstein condensation of magnons, alpha_(BEC) = 1.5. The scaling results are of direct relevance to the spin-dimer systems TlCuCl_3 and KCuCl_3, and explain the broad range of exponents reported for field-induced ordering transitions.Comment: 4 pages, 4 eps-figure

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