Moshe Schechter, Nicolas Laflorencie
Published 2005-11-12, updated 2006-08-24Version 2
Systems in which the dipolar energy dominates the magnetic interaction, and the crystal field generates strong anisotropy favoring the longitudinal interaction terms, are considered. Such systems in external magnetic field are expected to be a good experimental realization of the transverse field Ising model. With random interactions this model yields a spin glass to paramagnet phase transition as function of the transverse field. Here we show that the off-diagonal dipolar interaction, although effectively reduced, destroys the spin glass order at any finite transverse field. Moreover, the resulting correlation length is shown to be small near the crossover to the paramagnetic phase, in agreement with the behavior of the nonlinear susceptibility in the experiments on $\LHx$. Thus, we argue that the in these experiments a cross-over to the paramagnetic phase, and not quantum criticality, was observed.
Comments: To appear in Phys. Rev. Lett
Journal: Phys. Rev. Lett. 97, 137204 (2006)
Solving the Schroedinger equation for the Sherrington-Kirkpatrick model in a transverse field
Intermittency of dynamical phases in a quantum spin glass
Phase diagram of the $p$-spin-interacting spin glass with ferromagnetic bias and a transverse field in the infinite-$p$ limit
