Effective solution method of chemical reaction kinetics with diffuse

## 25+(1 -L)u,=O aty2=0 dyz to determine J,, we ensure that the zero-order solution does not have a boundary layer. In other words the higher-order terms will be of the order-of s/(1 -1) and, thus, will be small. Now, condition (8) is mathematically equivalent to d2u 2 = 0 dyt at yz = 0. (9)

## Abstract A new method of theoretical prediction of the kinetic rate constants of fast chemical reactions in solutions is presented. It takes into account the effect of finite diffusive displacements of the reacting molecules. The approach is based on the solution of the steady‐state Fokker–Planc

## Abstract The Tyson‐Fife reaction‐diffusion equations are solved numerically using a locally implicit approach. Since the variables evolve at very different time scales, the resulting system of equations is stiff. The reaction term is responsible for the stiffness and the time step is increased b

## Abstract The previously published equation for the rate of a diffusion‐limited bimolecular reaction between chemically asymmetric molecules is studied numerically for the case that one of the reactant molecules is uniform. The results are reproduced quite well by a simple approximate chemical‐ki