Spin-glass phase transition and behavior of nonlinear susceptibility in the Sherrington-Kirkpatrick model with random fields

Abstract

The behavior of the nonlinear susceptibility 3 and its relation to the spin-glass transition temperature Tf, in the presence of random fields, are investigated. To accomplish this task, the Sherrington-Kirkpatrick model is studied through the replica formalism, within a one-step replica-symmetry-breaking procedure. In addition, the dependence of the Almeida-Thouless eigenvalue λ AT (replicon) on the random fields is analyzed. Particularly, in absence of random fields, the temperature Tf can be traced by a divergence in the spin-glass susceptibility SG, which presents a term inversely proportional to the replicon λ AT. As a result of a relation between SG and 3, the latter also presents a divergence at Tf, which comes as a direct consequence of λ AT=0 at Tf. However, our results show that, in the presence of random fields, 3 presents a rounded maximum at a temperature T*, which does not coincide with the spin-glass transition temperature Tf (i.e., T* > Tf for a given applied random field). Thus, the maximum value of 3 at T* reflects the effects of the random fields in the paramagnetic phase, instead of the non-trivial ergodicity breaking associated with the spin-glass phase transition. It is also shown that 3 still maintains a dependence on the replicon λ AT, although in a more complicated way, as compared with the case without random fields. These results are discussed in view of recent observations in the LiHoxY1-xF4 compound.