To describe the non-equilibrium dynamics of random systems, we have recently introduced (Monthus and Garel, 2008 J. Phys. A: Math. Theor. 41 255002) a 'strong disorder renormalization' (RG) procedure in configuration space that can be defined for any master equation. In the present paper, we analyze in detail the properties of the large time dynamics whenever the RG flow is towards some 'infinite disorder' fixed point, where the width of the renormalized barrier distribution grows indefinitely upon iteration. In particular, we show how the strong disorder RG rules can be then simplified while keeping their asymptotic exactness, because the preferred exit channel out of a given renormalized valley typically dominates asymptotically over the other exit channels. We explain why the present approach is an explicit construction favoring the droplet scaling picture where the dynamics is governed by the logarithmic growth of the coherence length l(t) similar to (ln t)(1/psi), and where the statistics of barriers corresponds to a very strong hierarchy of valleys within valleys. As an example of application, we have followed numerically the RG flow for the case of a directed polymer in a two-dimensional random medium. The full RG rules are used to check that the RG flow is towards some infinite disorder fixed point, whereas the simplified RG rules allow us to study bigger sizes and to estimate the barrier exponent psi of the fixed point.

• 出版日期2008-7
• 单位中国地震局