Lecture 1 - Introduction to charge transport and its relevance to electrochemical energy system
Lecture 2 - Conservation of ion and Nernst Planck Equations
Lecture 3 - The advection-diffusion migration framework
Lecture 4 - Poisson Equation for the electric potential distribution
Lecture 5 - Electric Double Layer (EDL) and its structure
Lecture 6 - Approximate models of the EDL, and the electric potential distribution
Lecture 7 - Basics of Electrokinetic phenomena - I
Lecture 8 - Basics of Electrokinetic phenomena - II
Lecture 9 - Solute transport through the pores of membrane
Lecture 10 - Prediction of pore charge density and solute flux
Lecture 11 - Basics of hydrodynamic transport in porous media: Relevance to membrane based Electrolyser and Fuel cells
Lecture 12 - Introduction to Saffman Taylor instability
Lecture 13 - Analysis of multiphase transport in porous media
Lecture 14 - Liquid vapour transport in porous media
Lecture 15 - Transport of neutral solute through the porous-walled microchannel
Lecture 16 - Transport of charged solute through the porous-walled microchannel
Lecture 17 - Introduction to design of green H2 units
Lecture 18 - Modelling framework of individual standalone unit
Lecture 19 - Transport process in membrane electrolytes - Part I
Lecture 20 - Transport process in membrane electrolytes - Part II
