Random Transverse Field Ising Model in dimension d>1 : scaling analysis in the disordered phase from the Directed Polymer model

Abstract

For the quantum Ising model with ferromagnetic random couplings Ji,j>0 and random transverse fields hi>0 at zero temperature in finite dimensions d>1, we consider the lowest-order contributions in perturbation theory in (Ji,j/hi) to obtain some information on the statistics of various observables in the disordered phase. We find that the two-point correlation scales as : C(r) - rtyp +rω u, where typ is the typical correlation length, u is a random variable, and ω coincides with the droplet exponent ωDP(D=d-1) of the Directed Polymer with D=(d-1) transverse directions. Our main conclusions are (i) whenever ω>0, the quantum model is governed by an Infinite-Disorder fixed point : there are two distinct correlation length exponents related by typ=(1-ω)av ; the distribution of the local susceptibility loc presents the power-law tail P(loc) 1/loc1+μ where μ vanishes as av-ω , so that the averaged local susceptibility diverges in a finite neighborhood 0<μ<1 before criticality (Griffiths phase) ; the dynamical exponent z diverges near criticality as z=d/μ avω (ii) in dimensions d ≤ 3, any infinitesimal disorder flows towards this Infinite-Disorder fixed point with ω(d)>0 (for instance ω(d=2)=1/3 and ω(d=3) 0.24) (iii) in finite dimensions d > 3, a finite disorder strength is necessary to flow towards the Infinite-Disorder fixed point with ω(d)>0 (for instance ω(d=4) 0.19), whereas a Finite-Disorder fixed point remains possible for a small enough disorder strength. For the Cayley tree of effective dimension d=∞ where ω=0, we discuss the similarities and differences with the case of finite dimensions.