A formal rate law for non-faradaic electrode reactions

In recent work we have derived formal rate laws for faradaic 1 and nonfaradaic 2 electrode processes. A characteristic of these types of processes is that they couple two otherwise independent components of the phases bordering the solutionelectrode interphase. In the present work we concern ourselv

It is shown that the standard rate law for thermal decomposition of diatomic molecules, AB, in mixtures with an inert species, M, breaks down severely under conditions of vibrational disequilibrium, even when the time scales for relaxation and dissociation

A mathematical description of component enzymatic reactions is developed as a first step toward a method of analysis for biochemical systems. This serves to emphasize the particular non-linearities encountered in these components. For a broad class of enzymatic mechanisms the general form of the rat

The effective steady state rate constants for the bimolecular annihilation At A-t0 accompanied by unimolecular decay, A+O, and particle generation, S-A, are calculated in spatial dimensions d= 1, 2, 3 using the fluctuation dissipation theory. Non-classical (concentration dependent) rate constants at