Course catalogue
Create your own master’s programme by choosing between the different specializations of our partner universities.
string(4) "1130"
Academic Programme
Implemented from September 2025
Introduction to solid state (5 ECTS)
Semester 1
+
All courses during this semester
- Experimental methods on innovative research infrastructures - 5 ECTS
- Digital Micro-certification "The challenges of sustainable chemistry" - 10h
- Transferable skills : French language & interculturality (3 ECTS)
- Quantum mechanics towars quantum computing (5 ECTS)
- Winter school in Data Science (2 ECTS)
- Organic / Inorganic chemistry towards sustainability (5 ECTS)
- Kinetics and Electrochemistry (5 ECTS)
- Introduction to biophysics and microscopies for life science (5 ECTS)
Semester 2
+
All courses during this semester
- Luminescence spectroscopy of Lanthanides (3 ECTS)
- Summer School in Entrepreneurship (5 ECTS)
- Transferable skills: Polish course (3 ECTS)
- The molecules of life: from structure to chemical function (5 ECTS)
- Thermodynamics and soft matter (3 ECTS)
- Introduction to solid state (5 ECTS)
- Tech-infused perspectives on photochemical reaction dynamics (6 ECTS)
- Transferable skills: Portuguese course (3 ECTS)
- Summer School in Entrepreneurship (5 ECTS)
- Solid State Physics (5 ECTS)
- Molecular Energetics (3 ECTS)
- Laboratory of Materials and Surface Analysis (5 ECTS)
- Interfacial Electrochemistry (3 ECTS)
- Interfaces, Colloids and Self-Assembly (6 ECTS)
Semester 3
+
All courses during this semester
- 1-year research project - master thesis (equivalent 45 ECTS)
- Progress assessment of the research project (equivalent 6 ECTS)
- Weekly seminars (equivalent 4 ECTS)
- Special Topics in Chemistry (equivalent 5 ECTS)
- French language courses (3 ECTS)
- Nanosciences (6 ECTS)
- Medical applications of nanomaterials and radiations (6 ECTS)
- Top management, corporate law, and project writing for technology transfer and decision making (4 ECTS)
- Tracking ultrafast radiation-induced reactivity (3 ECTS)
- Applications for renewable energy and storage: solar fuels, batteries and hydrogen (6 ECTS) (6 ECTS)
- Scientific Writing and career objectives (2 ECTS)
- Surface Science and Nanostructuring at Surfaces (6 ECTS)
- Polymers for electronics and energy harvesting (5 ECTS)
- Electrochemical systems for fuel and electrolysis cells and batteries (6 ECTS)
- Project-based laboratory on device building (3 ECTS)
- Italian Courses (3 ECTS)
- Chemistry and Technology of Catalysis (5 ECTS)
Content
Auditorium lectures :
- Definitions of solid state and crystals.
- Classification of crystals – cohesion forces.
- Properties of crystals – anisotropy, phonons, band structure, conductivity.
- Point and space symmetry.
- Defects and surfaces.
- Diffraction: x-rays and neutrons at ambient and extreme conditions.
- TEM, SEM, AFM, STM.
- Inelastic scattering.
- Databases and data mining.
- Examples of applications: geophysics, electronics, sensors, energy harvesting.
Laboratory exercises:
- Crystals as the main representatives of solids.
- Symmetry as the main concept describing the crystal structure.
- From morphology to the structure.
- Space symmetry.
- X-Ray diffraction – reciprocal space.
- Database search and understanding crystallographic information.
Journal club : 5 meetings with student seminars presenting assignments from current literature with discussion.
Aims
The course will teach the students:
- how to define the solid state and to connect its 3D structure with properties.
- how the knowledge about 3D structures in databases facilitates the understanding of structure-property relations;
- how this knowledge is applied in the development of modern materials;
- how to practically investigate the symmetry, structure and properties of solids in a modern diffraction and spectroscopy labs.
Recommended Books
- Gale Rhodes, Crystallography Made Crystal Clear, 3rd edition, Academic Press, Amsterdam 2006.
- Harry R. Allcock, Introduction to materials chemistry, Wiley, New Jersey 2008.
- Gregory S. Rohrer, Structure and Bonding in Crystalline Materials, Cambridge University Press 2001.
- Max Born & Huang Kun, Dynamical Theory of Crystal Lattices, Oxford Science Publications, 1988.
Teaching Staff
Prof. Andrzej Katrusiak
Dr. Ewa Patyk-Kaźmierczak
Hours
Lectures: 30h
Tutorials: 45h