TY - JOUR
T1 - Metastability for reversible probabilistic cellular automata with self-interaction
AU - Cirillo, Emilio N.M.
AU - Nardi, Francesca R.
AU - Spitoni, Cristian
N1 - Funding Information:
Acknowledgements One of the authors (ENMC) acknowledges Eurandom for the kind hospitality. CS would like to thank Anton Bovier for his kind hospitality at Weierstrass-Institut (Berlin). The work of FRN was supported by Dipartimento di Matematica, Università di Roma Tre. The work of CS was partially supported by Dipartimento Me. Mo. Mat., Università di Roma “La Sapienza.”
PY - 2008/8
Y1 - 2008/8
N2 - The problem of metastability for a stochastic dynamics with a parallel updating rule is addressed in the Freidlin-Wentzel regime, namely, finite volume, small magnetic field, and small temperature. The model is characterized by the existence of many fixed points and cyclic pairs of the zero temperature dynamics, in which the system can be trapped in its way to the stable phase. Our strategy is based on recent powerful approaches, not needing a complete description of the fixed points of the dynamics, but relying on few model dependent results. We compute the exit time, in the sense of logarithmic equivalence, and characterize the critical droplet that is necessarily visited by the system during its excursion from the metastable to the stable state. We need to supply two model dependent inputs: (1) the communication energy, that is the minimal energy barrier that the system must overcome to reach the stable state starting from the metastable one; (2) a recurrence property stating that for any configuration different from the metastable state there exists a path, starting from such a configuration and reaching a lower energy state, such that its maximal energy is lower than the communication energy.
AB - The problem of metastability for a stochastic dynamics with a parallel updating rule is addressed in the Freidlin-Wentzel regime, namely, finite volume, small magnetic field, and small temperature. The model is characterized by the existence of many fixed points and cyclic pairs of the zero temperature dynamics, in which the system can be trapped in its way to the stable phase. Our strategy is based on recent powerful approaches, not needing a complete description of the fixed points of the dynamics, but relying on few model dependent results. We compute the exit time, in the sense of logarithmic equivalence, and characterize the critical droplet that is necessarily visited by the system during its excursion from the metastable to the stable state. We need to supply two model dependent inputs: (1) the communication energy, that is the minimal energy barrier that the system must overcome to reach the stable state starting from the metastable one; (2) a recurrence property stating that for any configuration different from the metastable state there exists a path, starting from such a configuration and reaching a lower energy state, such that its maximal energy is lower than the communication energy.
KW - Low temperature dynamics
KW - Metastability
KW - Probabilistic cellular automata
KW - Stochastic dynamics
UR - http://www.scopus.com/inward/record.url?scp=46249090845&partnerID=8YFLogxK
U2 - 10.1007/s10955-008-9563-6
DO - 10.1007/s10955-008-9563-6
M3 - Article
AN - SCOPUS:46249090845
SN - 0022-4715
VL - 132
SP - 431
EP - 471
JO - Journal of Statistical Physics
JF - Journal of Statistical Physics
IS - 3
ER -