Interfacial Reaction Kinetics
Abstract
We study irreversible A-B reaction kinetics at a fixed interface separating two immiscible bulk phases, A and B. We consider general dynamical exponent z, where xt t1/z is the rms diffusion distance after time t. At short times the number of reactions per unit area, Rt, is 2nd order in the far-field reactant densities nA∞,nB∞. For spatial dimensions d above a critical value dc=z-1, simple mean field (MF) kinetics pertain, Rt Qb t nA∞ nB∞ where Qb is the local reactivity. For low dimensions d<dc, this MF regime is followed by 2nd order diffusion controlled (DC) kinetics, Rt ≈ xtd+1 nA∞ nB∞, provided Qb > Qb* (nB∞)[z-(d+1)]/d. Logarithmic corrections arise in marginal cases. At long times, a cross-over to 1st order DC kinetics occurs: Rt ≈ xt nA∞. A density depletion hole grows on the more dilute A side. In the symmetric case (nA∞=nB∞), when d<dc the long time decay of the interfacial reactant density, nAs, is determined by fluctuations in the initial reactant distribution, giving nAs t-d/(2z). Correspondingly, A-rich and B-rich regions develop at the interface analogously to the segregation effects established by other authors for the bulk reaction A+B. For d>dc fluctuations are unimportant: local mean field theory applies at the interface (joint density distribution approximating the product of A and B densities) and nAs t(1-z)/(2z). We apply our results to simple molecules (Fickian diffusion, z=2) and to several models of short-time polymer diffusion (z>2).
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