Syllabus, Bachelor's level, 1KB204
- Education cycle
- First cycle
- Main field(s) of study and in-depth level
- Chemistry G2F, Technology G2F
- Grading system
- Fail (U), Pass (3), Pass with credit (4), Pass with distinction (5)
- Finalised by
- The Faculty Board of Science and Technology, 1 November 2010
- Responsible department
- Department of Chemistry - Ångström
After completing the course the student should be able to
- apply Nernst equation and the Tafel equation to different electrochemical systems
- define the term overpotential, explain its origin and the relationship between current and potential for some types of electrochemical cells
- predict how the conductivity of an electrolyte depends on the electrolyte concentration and type and explain the origin of ion conductivity in some solid electrolytes
- apply some common electrochemical methods to electrochemical systems and explain which type of information that can be obtained with these techniques
- describe different types of corrosion as well as explain the origin and course of the corrosion processes
- record polarisation curves for different materials and explain which type of information that can be obtained with this technique
- calculate corrosion rates and describe some common methods used to prevent or control corrosion processes
- explain the function of batteries and fuel cells.
General electrochemical concepts. Introduction to electrochemistry: thermodynamics, electrode potentials, galvanic and electrolytic cells, electrode kinetics, dynamic electrochemistry, mass transport by migration, diffusion and convection, diffusion layers. Conductivity. Liquid and solid electrolytes. Solid and liquid ionic conductors. The electrochemical double layer. Overpotentials. Electrochemical instrumentation and techniques. Potentiostatic and galvanostatic experiments. Cyclic voltammetry, chronoamperometry, chronopotentiometry. Électrochemical syntheses of solid materials. Solid state electrochemistry. Intercalation processes. Corrosion. Types of corrosions and corrosion protection. Mixed potentials. Corrosion rates. Polarisation curves.
Experimental work illustrating selected parts of the theoretical content.
Lectures, seminars, laboratory work.
Written examination at the end of the course (4 credits). Passed laboratory course is required and is assigned 1 credit.