The requirements for qualifying the laboratory will stand alone, followed by the lecture. Students will attend a 2-hour theoretical lecture, acquiring a solid theoretical background in electrochemical impedance spectroscopy and gaining instructions on the measurement method and laboratory procedures. Subsequently, students will spend 5 hours actively engaging in planned experiments, gathering impedance data from fuel cell systems. Upon collecting the experimental data, students will dedicate the remaining time to data analysis and report writing. They will analyze the data, interpret the results, and draw meaningful conclusions based on their findings. The final assessment criterion will be the laboratory report, which will require students to demonstrate a strong understanding of electrochemical impedance spectroscopy theory, proficiency in the measurement process, appropriate data processing methodologies, and an insightful interpretation.
Equipped with state-of-the-art facilities, the laboratory offers a comprehensive learning experience, providing students with advanced practical knowledge and an in-depth practical understanding of fuel cell systems. A focal point of the laboratory is the study of Electrochemical Impedance Spectroscopy (EIS) and its applications for fuel cell diagnosis. Through practical experimentation, students will gain proficiency in utilizing EIS as a powerful diagnostic tool for electrochemical systems. By analyzing impedance spectra at various frequencies, they acquire insights into the fuel cell's performance and health, enhancing their understanding of electrochemical processes. In addition to EIS, students also receive hands-on experience with MATLAB, an essential analysis tool for processing and interpreting experimental data.
Master-Module (2V/1Ü)
Module Language: English
Elective Area Module
Sunil Kumar, M. Eng.
The laboratory will be offered on three dates in January 2024.
Please join the corresponding Stud.IP Course "FUS Diagnosis Laboratory" for registration to one of them.