Experimental current distribution in porous battery electrodes

PRACTICAL considerations in the construction of electrochemical energy conversion devices, operating with a continuous supply of reactant and removal of products, necessitate high current densities at low overpotentials, Hence, the current distribution within the porous electrode structure and the e

## AhEtmct-This paper presents an experimental study of metal-solution potential distributions in fiowthrough porous electrodes of fixed beds of spherical conducting particles. The distributions are determined when the electrodes are working at the limiting diffusion current. They are shown to be

Abstnw-A ma&mat& model to represent porous electrodes assummg that the electrochenucal reaction has a Tafel kmetlc control IS proposed ExpressIons are developed to analyse the performance of the electrode and the effect of the geometnc parameters on the effectiveness IS dlscussed The theorettcal res

A numerical model of flow-through porous electrodes is presented. This model simulates the distribution of potential and current density within a porous electrode. The model includes consideration of the electron transfer control regime of the electrode reaction, mass transport limitations and the f