Abstract

Abstract The Noyes and Smoluehowski diffusion-limited reaction rate theories are proved to be equivalent on a lattice. The Noyes theory is analysed and used to predict the kinetics of the two-dimensional irreversible reaction A + B → P. Only condensed phase reactions with molecules of A and B undergoing Brownian motion (diffusion) are discussed. For comparison, all calculations are done in both two and three dimensions. The two-dimensional rate functionkN(t) in the equation d[A]/dt = d[B]/dt = -kN(t) [A] [B] asymptotically goes to zero as (In t)-1 as t increases; the asymptotic expansion of kN(t) is derived from the expansion for the first-return probability in a random walk on a square lattice. The theoretical rate function is determined as a function of the probability α of reaction given an encounter. Although kN(t) is not significantly different from ‘empirical’ rate functions in a Monte Carlo simulation of a two-dimensional chemical reaction, it does differ from the rate function in a two-dimensional fluorescence quenching experiment.