Spectroscopy: Instrumentation and Theory
Course, Master's level, 1FA035
Expand the information below to show details on how to apply and entry requirements.
Spring 2026 Spring 2026, Uppsala, 33%, On-campus, Swedish
- Location
- Uppsala
- Pace of study
- 33%
- Teaching form
- On-campus
- Instructional time
- Daytime
- Study period
- 19 January 2026–22 March 2026
- Language of instruction
- Swedish
- Entry requirements
-
120 credits in science/engineering. Participation in Quantum Physics or Quantum Physics F. Proficiency in English equivalent to the Swedish upper secondary course English 6.
- Selection
-
Higher education credits in science and engineering (maximum 240 credits)
- Fees
- If you are not a citizen of a European Union (EU) or European Economic Area (EEA) country, or Switzerland, you are required to pay application and tuition fees.
- First tuition fee instalment: SEK 12,083
- Total tuition fee: SEK 12,083
- Application deadline
- 15 October 2025
- Application code
- UU-63148
Admitted or on the waiting list?
- Registration period
- 19 December 2025–18 January 2026
- Information on registration from the department
Spring 2026 Spring 2026, Uppsala, 33%, On-campus, Swedish For exchange students
- Location
- Uppsala
- Pace of study
- 33%
- Teaching form
- On-campus
- Instructional time
- Daytime
- Study period
- 19 January 2026–22 March 2026
- Language of instruction
- Swedish
- Entry requirements
-
120 credits in science/engineering. Participation in Quantum Physics or Quantum Physics F. Proficiency in English equivalent to the Swedish upper secondary course English 6.
Admitted or on the waiting list?
- Registration period
- 19 December 2025–18 January 2026
- Information on registration from the department
About the course
This course provides you with a practical and theoretical basis regarding spectroscopy, combining quantum mechanical principles with modern experimental techniques. You will learn to model and analyse quantum systems, interpret spectroscopic data, and evaluate the capabilities of various spectroscopic methods for probing material properties. The course covers key topics such as time-dependent and time-independent quantum mechanics, spectral line shapes, data analysis using advanced techniques like machine learning, and visualisation of results. Applications include particle accelerators, nuclear reactors, fusion plasmas, astronomy, and materials science. Hands-on laboratory exercises include techniques such as time-resolved laser spectroscopy, Raman spectroscopy, scanning tunnelling microscopy, and X-ray photoelectron spectroscopy.
Reading list
No reading list found.