Critical dynamic approach to stationary states in complex systems

A dynamic scaling Ansatz for the approach to stationary states in complex systems is proposed and tested by means of extensive simulations applied to both the Bak-Sneppen (BS) model, which exhibits robust Self-Organised Critical (SOC) behaviour, and the Came of Life (GOL) of J. Conway, whose critical behaviour is under debate. Considering the dynamic scaling behaviour of the density of sites (rho(t)), it is shown that i) by starting the dynamic measurements with configurations such that rho(t = 0) -> 0, one observes an initial increase of the density with exponents theta = 0.12(2) and theta = 0.11(2) for the BS and GOL models, respectively; ii) by using initial configurations with rho(t = 0) -> 1, the density decays with exponents delta = 0.47(2) and delta = 0.28(2) for the BS and GOL models, respectively. It is also shown that the temporal autocorrelation decays with exponents C-a = 0.35(2) (C-a = 0.35(5)) for the BS (GOL) model. By using these dynamically determined critical exponents and suitable scaling relationships, we also obtain the dynamic exponents z = 2.10(5) (z = 2.10(5)) for the BS (GOL) model. Based on this evidence we conclude that the dynamic approach to stationary states of the investigated models can be described by suitable power-law functions of time with well-defined exponents.