Influence of thermal fluctuations on the geometry of the interfaces of the quenched Ising model

Abstract

We study the role of the quench temperature Tf in the phase-ordering kinetics of the Ising model with single spin flip in d=2,3. Equilibrium interfaces are flat at Tf=0, whereas at Tf>0 they are curved and rough (above the roughening temperature in d=3). We show, by means of scaling arguments and numerical simulations, that this geometrical difference is important for the phase-ordering kinetics as well. In particular, while the growth exponent z=2 of the size of domains L(t) t1/z is unaffected by Tf, other exponents related to the interface geometry take different values at Tf=0 or Tf>0. For Tf>0 a crossover phenomenon is observed from an early stage where interfaces are still flat and the system behaves as at Tf=0, to the asymptotic regime with curved interfaces characteristic of Tf>0. Furthermore, it is shown that the roughening length, although sub-dominant with respect to L(t), produces appreciable correction to scaling up to very long times in d=2.