Course Objective(s):
The course aims to acquaint the students with the advanced aspects of electrochemistry so that they can understand the mechanism and processes of battery, fuel cell, corrosion and electro-catalysis.
Course Outcomes (COs):
Course Outcomes
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Teaching Learning Strategies |
Assessment Strategies |
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After the completion of this course, students will be able to- CO172- compare different batteries and select an appropriate one as per requirement. CO173- illustrate the concept of corrosion, corrosion inhibition and apply thermodynamics to discuss the stability of a metal. CO174- discuss the principle of different type of fuel cells, their properties and applications. CO175- explain the concept, mechanism, types and factors affecting electrocatalysis. CO176- describe electrochemical phenomenon related to the environment. |
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Properties of electrochemical energy devices- Discharge plot, Ragone plot, measure of battery performance, charging and discharging of batteries, electrochemical capacitors as energy storage device, storage density, energy density.
Classical Batteries- (i) Lead Acid (ii) Nickel –Cadmium (iii) Zinc – Manganese dioxide
Modern Batteries- (i) Zinc- Air (ii) Nickel – Metal Hydride (iii) Lithium Battery (iv) Lithium ion Battery.
Electrochemical corrosion of metals, thermodynamics and stability of metals, potential–pH (or Pourbaix) diagrams, uses and abuses, corrosion current and corrosion potential- Evans diagram.
Measurement of corrosion rate- weight loss method and electrochemical method.
Inhibition of corrosion- cathodic and anodic protection (i) by addition of substances to the electrolytic environment (ii) by charging corroding metal from external source, organic inhibition: Fuller story, green inhibitors.
Passivation- nature of the passive layer, structure of the passive film, methods of passivation, depassivation, localized corrosion.
Electrochemical generators (Fuel Cells)- efficiency, kinetics of fuel cell reactions, types of fuel cells- alkaline fuel cell, phosphoric acid fuel cell, high temperature fuel cell, solid polymer electrolyte fuel cell, direct MeOH fuel cell, molten carbonate fuel cell, solid oxide fuel cell, applications of fuel cells.
Energy options- hydrogen economy, introduction, hydrogen production, hydrogen transmission, storage and distribution, hydrogen fueled equipment, local electricity production from hydrogen, hazards and safety aspects of hydrogen.
Chemical catalysis and electrocatalysis, cathodic and anodic electro catalysis, electrocatalysis and adsorption effects, mechanism of electrocatalysis, volcanoes, metal electrodes-influence of the nature of the metal, influence of surface state and structure, highly dispersed metal catalyst, binary and multicomponent metal catalysts (metal alloys and atoms), non-metallic catalysts, metal complexes with organic ligands.
Bio catalysis- enzymes, immobilization, practical application of enzymes as electrode.
Environmentally oriented electrochemistry- electrochemistry of water splitting, superelectrolyzers, photo electrochemical splitting of water, solar hydrogen production, fixing of CO2, mechanism of CO2 reduction, photochemical reduction of CO2, removal of wastes. Electrochemical decontamination of soil.
Electrochemical sensors- enzyme based sensors, affinity biosensors, gas sensors.
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