Laszlo Kornyei, Michel Pleimling, Ferenc Igloi
Published 2005-09-14Version 1
We consider nonequilibrium critical dynamics of the two-dimensional Ising model for which the initial state is prepared by switching on random fields with zero mean and variance $H$. In the initial state there is no magnetic order but the clusters of parallel spins have a percolation transition for small enough $H$. Using heath-bath dynamics we measure the relaxation of the magnetization which shows a reentrance in time. Due to cluster dissolution in the early time regime there is a decrease of the magnetization, followed by an increase due to nonequilibrium domain growth which itself turns to a decrease due to equilibrium relaxation. The power law decay of the nonequilibrium autocorrelation function is not influenced by the percolation in the initial state.
Comments: 7 pages, 4 figues, submitted to Europhysics Letters
Journal: Europhys. Lett. 73, 197-203 (2006)
Quantum Quenches to a Critical Point in One Dimension: some further results
Power law decay of entanglement quantifiers in a single agent to a many body system coupling
Dynamical critical scaling and effective thermalization in quantum quenches: the role of the initial state
