13M061FKSM - Physics of Condensed Matter and Contemporary Materials

Course specification
Course title Physics of Condensed Matter and Contemporary Materials
Acronym 13M061FKSM
Study programme Electrical Engineering and Computing
Module Biomedical and Environmental Engineering
Type of study master academic studies
Lecturer (for classes)
Lecturer/Associate (for practice)
Lecturer/Associate (for OTC)
    ESPB 6.0 Status elective
    Condition None
    The goal Provide master students with basic knowledge on quantum chemistry of macromolecules and physics of condensed matter, as well as on properties and engineering of various classes of biomaterials and electromaterials.
    The outcome At the end of this course students should know how to: - Have a deeper understanding of biomaterials and electro materials - Have a wider perspective of the possibility of material engineering in biomedicine and electrical engineering
    Contents of lectures Quantum chemistry of macromolecules (Hybridization of orbitals. Structure and dynamics). Physics of Condensed Matter (Quasiparticles. Structure and dynamics). Biomaterials (Metals. Ceramics. Polymers. Composites. Bioderivative tissues). Electromaterials (Semiconductors, Carbon materials, Conductive polymers. Conductors, Superconductors. Dielectrics, Photonic crystals. Magnetics, Metamaterials).
    Contents of exercises Practices, seminars and demonstrations in other centres and laboratories.
    1. D.Raković, Physical Fundamentals and Properties of Electroengineering Materials, AM, 2000.
    2. Group of authors, Biomaterials, D.Raković, D.Uskoković, eds., Institute of Technical Sciences SASA & MRS Serbia, Belgrade, 2010.
    3. D.Raković, Fundamentals of Biophysics, 3. ed., IASC & IEFPG, Belgrade, 2008.
    4. L.A.Gribov, S.P.Mushtakova, Kvantovaya himiya, Gardariki, Moskva, 1999, In Russian.
    5. DVD with Ppt-presentations and additional literature.
    Number of hours per week during the semester/trimester/year
    Lectures Exercises OTC Study and Research Other classes
    2 2
    Methods of teaching 30 hours of lectures and seminars + 30 hours of practices, seminars and demonstrations in other centres and laboratories, student seminars with presentations, pre-exam by the end of semestre. Approximately 75 hours of personal study and exercise (3 hours per week during semestre, and approximately 30 hours of preparation during exam term).
    Knowledge score (maximum points 100)
    Pre obligations Points Final exam Points
    Activites during lectures 10 Test paper 50
    Practical lessons 0 Oral examination 0
    Seminars 40