{"id":322,"date":"2015-03-06T10:31:17","date_gmt":"2015-03-06T15:31:17","guid":{"rendered":"http:\/\/www.joshuagallaway.com\/?p=322"},"modified":"2020-03-17T20:35:50","modified_gmt":"2020-03-18T00:35:50","slug":"modeling-porous-electrodes-part-2","status":"publish","type":"post","link":"https:\/\/www.joshuagallaway.com\/?p=322","title":{"rendered":"Modeling porous electrodes: Part 2"},"content":{"rendered":"

A secondary current distribution model considers:<\/p>\n

    \n
  1. Ohm’s law resistance, and<\/li>\n
  2. kinetic charge-transfer resistance<\/li>\n<\/ol>\n

    while resistance related to concentration variations is ignored. Beginning with the equations given in Modeling porous electrodes: Part 1<\/a>, the following can be written:<\/p>\n

    \"Porous<\/a><\/p>\n

    Eq 1 is conservation of charge; Eq 2 is some expression of electrochemical reaction kinetics; and Eqs 3 & 4 are Ohm’s law for the solid and liquid phases. The boundary conditions are such that a current density of I<\/em> is being produced by the electrode. The liquid phase potential\u00a0\u03c6<\/em>2<\/sub> is arbitrarily set to 0 V at x = 0. The specific expression for the electrode kinetics (Eq 2) needs to be specified. The concentration-independent Butler-Volmer expression can be used:<\/p>\n

    \"Porous-2-Butler-Volmer.png\"<\/a><\/p>\n

    The left hand side of this expression is the transfer current, with units of A\/cm3<\/sup>, and gives the amount of electrochemical reaction occurring at any point. The right hand side has two components: the anodic and cathodic kinetic terms. The downside of the Butler-Volmer equation is its complexity. Finding an analytical solution to the above set of differential equations requires a more simplified kinetic expression. One possible simplification is to assume the overpotential (\u03c6<\/em>1\u00a0<\/sub>–\u00a0\u03c6<\/em>2<\/sub>) is highly negative. This means only the cathodic term in the Butler-Volmer equation need be considered:<\/p>\n

    \"Porous-2-Tafel\"<\/a><\/p>\n

    The right hand side of this expression is a form of the Tafel equation. (An analogous anodic form can be used when overpotential is highly positive.) Another possible simplification is to assume\u00a0the overpotential (\u03c6<\/em>1<\/sub>\u00a0–\u00a0\u03c6<\/em>2<\/sub>) is small. In this case both anodic and cathodic terms are important. Substituting the first two terms of a Taylor series for the exponentials results in:<\/p>\n

    \"Porous-2-linear\"<\/a><\/p>\n

    This linear kinetic expression is valid only at low currents. Which approximation of the kinetic expression is appropriate depends on the conditions of interest. Choosing the following values for physical parameters:<\/p>\n