Core course in MSc Chemistry (Energy & Sustainability), Elective course MSc Life Science and Technology.
Basic knowledge of photochemistry and spectroscopy.
In photosynthesis, the Sun’s energy is captured and stored by a series of events that convert the pure energy of light into the biochemical energy needed to power life. This course describes the molecular processes in photosynthesis from light capture to carbon fixation, with a special focus on the early events. The first part will focus on the biophysical concepts and design principles of natural photosynthesis, with relevance for artificial photosynthesis. The second part will focus on regulation in oxygenic photosynthesis. In addition, the course will contain 1-2 sessions concentrated on scientific reading papers covering a specific theme. During these sessions, students will give an oral presentation of an assigned reading paper, followed by group discussion. While this course is a core module for Chemistry (Energy & Sustainability), Life Science and Technology students with interest in green biology are encouraged to join.
Course material contains chapters from the book “Molecular Mechanisms in Photosynthesis” (R.E. Blankenship, Wiley 2nd edition 2014) and distributed lecture slides. Students are expected to have a basic background knowledge in photochemistry and spectroscopy. The appendix of the course book also provides an elementary overview of common spectroscopy and techniques used in photosynthesis.
Aims of this course
After this course, students will be able to
- read and discuss scientific literature on selected photochemical/photophysical topics in photosynthesis
- explain molecular mechanisms underlying photophysical/photochemical processes in photosynthesis
- apply theory of excitation and electron transfer to calculate energy transfer, quantum yields, conversion efficiencies and losses in photosynthetic networks explain current molecular models for photoprotection.
Course lectures, 4 hours/week.
Molecular Mechanisms of Photosynthesis, 2nd Edition
Robert E. Blankenship
April 2014, Wiley-Blackwell
The book is available as e-book.
Written exam (80%) and oral presentation/discussion (20%).