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CHEE 363  Electrochemical Engineering  Units: 3.50  
This engineering science course covers aspects of technological applications of electrochemistry. It can be considered as overlap between electrical engineering, electrochemistry and chemical engineering. The course addresses the following 7 major topics of electrochemical engineering: 1) Introduction into Electrochemical Engineering and Systems: Characteristics, Charge Conservation, Faraday's Law; 2) Elements of Electrochemical Systems I. Electrolytes: Transport processes, electrolyte conductivity, pH and buffer solutions; 3) Elements of Electrochemical Systems II. Electrodes: Electrochemical Thermodynamics, Nernst Equation, Reference Electrodes, Cell Potential, Electrochemical Kinetics; 4) Electrical Double Layers: Theory & Models, Electrokinetic Phenomena; 5) Electrochemical Characterization Methods: Cyclic Voltammetry, Electrical Impedance Spectroscopy; 6) Electrochemical Energy Engineering: Batteries, Fuel Cells, Electrical & Electrochemical Capacitors; 7) Industrial Electrochemical Processes: Fundamentals, Reactor Design & Parameter, Chlor-Alkali Process, Electrochemical Extraction of Metals, Hall-Heroult Process.
(Lec: 3, Lab: 0, Tut: 0.5)
Requirements: Prerequisites: CHEE 210, CHEE 270, CHEE 321, or permission of the department. Corequisites: Exclusions: CHEE 461  
Offering Term: W  
CEAB Units:    
Mathematics 0  
Natural Sciences 0  
Complementary Studies 0  
Engineering Science 30  
Engineering Design 12  
Offering Faculty: Smith Engineering  

Course Learning Outcomes:

  1. Define and explain the concepts of Electrical Potential, Electrical Field, Electrostatic Work, Voltage, Current, Electrochemical Potential, Activation Energy, Electrode & Electrochemical Equilibrium.
  2. Formulate and calculate relevant transport phenomena such as migration and the characteristics of (diluted) electrolytesRelate the conversion of matter to the transport of electrical charge.
  3. Evaluate the potential of electrochemical systems based on thermodynamic data and the concept of half-cellsApply electrical circuit elements to model electrochemical systems in order to calculate energy balances and to estimate efficiencies.
  4. Apply knowledge of electrokinetic phenomena to design microfluidic unit operations.
  5. Use of technical measures to characterize properties of galvanic elements and capacitors.
  6. Demonstrate fundamental knowledge of major industrial electrochemical processes and electrochemical reactor design including economic and environmental considerations.