Interplay of phase segregation and chemical reaction: Crossover and effect on growth laws
Abstract
By combining the nonconserved spin-flip dynamics driving ferromagnetic ordering with the conserved Kawasaki-exchange dynamics driving phase segregation, we perform Monte Carlo simulations of the nearest neighbor Ising model. Such a set up mimics a system consisting of a binary mixture of isomers which is simultaneously undergoing a segregation and an interconversion reaction among themselves . Here, we study such a system following a quench from the high-temperature homogeneous phase to a temperature below the demixing transition. We monitor the growth of domains of both the winner, the isomer which survives as the majority and the loser, the isomer that perishes. Our results show a strong interplay of the two dynamics at early times leading to a growth of the average domain size of both the winner and loser as t1/7, slower than a purely phase-segregating system. At later times, eventually the dynamics becomes reaction dominated, and the winner exhibits a t1/2 growth, expected for a system with purely nonconserved dynamics. On the other hand, the loser at first show a faster growth, albeit, slower than the winner, and then starts to decay before it almost vanishes. Further, we estimate the time τs marking the crossover from the early-time slow growth to the late-time reaction dominated faster growth. As a function of the reaction probability pr, we observe a power-law scaling τs pr-x, where x≈ 1.05, irrespective of temperature. For a fixed value of pr too, τs appears to be independent of temperature.
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