Lecture 1 - Introduction
Lecture 2 - Challenges with Fossil Fuels
Lecture 3 - Renewable Energy and Hydrogen
Lecture 4 - Energy Consumption in Different Countries
Lecture 5 - Energy Consumption in Different Sectors
Lecture 6 - Economic Modelling
Lecture 7 - The Current Market for Hydrogen - I
Lecture 8 - The Current Market for Hydrogen - II
Lecture 9 - Hydrogen Production from Fossil Fuels - I
Lecture 10 - Hydrogen Production from Fossil Fuels - II
Lecture 11 - The Cost of Hydrogen Production from Fossil Fuels - I
Lecture 12 - The Cost of Hydrogen Production from Fossil Fuels - II
Lecture 13 - Carbon Capture from Fossil Fuel-based Hydrogen
Lecture 14 - The Production of Hydrogen from Renewable Sources
Lecture 15 - The Economics of Hydrogen Production by Electrolysis
Lecture 16 - Hydrogen Production from Biomass
Lecture 17 - Economics of Hydrogen Production from Biomass
Lecture 18 - Biomass Lab
Lecture 19 - Introduction to fuel cell and electrolyzers
Lecture 20 - Thermodynamics of fuel cell and electrolyzers - I
Lecture 21 - Thermodynamics of fuel cell and electrolyzers - II
Lecture 22 - Variation in reversible potential and the Nernst Equation
Lecture 23 - Nernst equation and Numerical Problems - I
Lecture 24 - Numerical Problems - II
Lecture 25 - Numerical Problems - III
Lecture 26 - Characteristic curve (I-V) of a fuel cell
Lecture 27 - Potential losses in fuel cells and electrolyzers
Lecture 28 - Fuel cell efficiency and numerical problems
Lecture 29 - Significance of current and power density
Lecture 30 - Significance of cell components
Lecture 31 - Cell stacking
Lecture 32 - Fabrication of the membrane electrode assembly
Lecture 33 - Introduction to Reaction kinetics of fuel cell - I
Lecture 34 - Reaction kinetics of fuel cell - II
Lecture 35 - Butler-Volmer equation - I
Lecture 36 - Butler-Volmer equation - II
Lecture 37 - Butler-Volmer and Taffel Equation - III
Lecture 38 - Charge Transport mechanism in fuel cell and electrolyzers
Lecture 39 - Charge Transport mechanism and numerical problems
Lecture 40 - Ohmic losses and significance of interfacial contact resistance
Lecture 41 - Mass transport in fuel cell and electrolyzers - 1
Lecture 42 - Mass Transport: Relationship Between Current and Diffusive Flux
Lecture 43 - Concentration loss and numerical problems
Lecture 44 - Bipolar plates and different flow field designs
Lecture 45 - Scale-up issues in fuel cell and electrolyzers
Lecture 46 - Laboratory Demonstrations
Lecture 47 - Hydrogen Storage and Transport - I
Lecture 48 - Hydrogen Storage and Transport - II
Lecture 49 - Cost of Hydrogen Storage
Lecture 50 - Cost of Hydrogen Storage and Transport
Lecture 51 - Mass Shipping of Hydrogen - I
Lecture 52 - Mass Shipping of Hydrogen - II
Lecture 53 - Mass Shipping of Hydrogen - III
Lecture 54 - Competitive Position of Hydrogen versus Fossil Fuels
Lecture 55 - Case Studies for Hydrogen Economy
Lecture 56 - Process Simulation of Hydrogen Energy Systems
Lecture 57 - Introduction to Life-cycle Assessment - I
Lecture 58 - Introduction to Life-cycle Assessment - II
Lecture 59 - Introduction to Life-cycle Assessment - III
Lecture 60 - LCA of Hydrogen Energy Systems
Lecture 61 - Case Study
