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13D061KIB - Quantum Informatics of Biomolecules

Course specification
Course title Quantum Informatics of Biomolecules
Acronym 13D061KIB
Study programme Electrical Engineering and Computing
Module Nuclear, Medical and Ecological Engineering
Type of study doctoral studies
Lecturer (for classes)
    Lecturer/Associate (for practice)
      Lecturer/Associate (for OTC)
        ESPB 9.0 Status elective
        Condition none
        The goal Provide students with contemporary notions and applications of quantum informatics in molecular biophysics.
        The outcome After completing this course students should be able to:  Comprehend deeply quantum-informational processes in molecular biophysics.
        Contents
        Contents of lectures Basics of quantum informatics (qubits, quantum entanglement, quantum teleportation, quantum computation, quantum decoherence). Quantum chemistry of biomolecules (degrees of freedom and subsitems of biomolecules and their interactions, spatial structure and dynamics of biomolecules). Levinthal classical paradox. Quantum informatics of biomolecules (conformational transitions, biomolecular recognition, photosynthesis).
        Contents of exercises
        Literature
        1. M.Dugić, Fundamentals of Quantum Information and Quantum Computation, Faculty of Science, Kragujevac, 2009, in Serbian.
        2. M.Dugić, Decoherence in Classical Limit of Quantum Mechanics, SFIN XVII (2), Institute of Physics, Belgrade, 2004, in Serbian.
        3. D.Raković, Fundamentals of Biophysics, 3. ed., IASC & IEFPG, Belgrade, 2008, in Serbian.
        4. J. Jeknić-Dugić, Decoherence Model of Conformational Transitions in Molecules, PhD Thesis, Faculty of Science, Kragujevac, 2010, in Serbian.
        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
        6
        Methods of teaching Lectures/supervision, student seminars with presentations. Approximately 90 hours of personal study and exercise (4 hours per week during semestre, and approximately 40 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 Oral examination
        Projects
        Colloquia
        Seminars 40