Scientific seminar on the specialty

Course: High Energy Physics

Structural unit: Faculty of Physics

Title
Scientific seminar on the specialty
Code
ВБ 4.4
Module type
Вибіркова дисципліна для ОП
Educational cycle
Second
Year of study when the component is delivered
2018/2019
Semester/trimester when the component is delivered
4 Semester
Number of ECTS credits allocated
3
Learning outcomes
Preparation of students for the presentation of master's theses for defense at the examination board and preparation of questions for the comprehensive exam.
Form of study
Full-time form
Prerequisites and co-requisites
1. Know the basic postulates of classical and relativistic mechanics and special theory of relativity; physical principles of operation of ionizing radiation detectors; characteristics of ionizing radiation; principle of operation of accelerators, algorithms and methods of experimental data processing. 2. Be able to present a master's thesis; clearly answer the questions submitted to the comprehensive state exam in physics; to orient in questions of modern physics. 3. Have an idea of physical phenomena and processes in subatomic structures,
Course content
formation of students' generalizations of high energy physics and nuclear physics through a set of knowledge close to the topics of master's research, to form approaches to the methodology of modern scientific and practical research, professional application of theoretical knowledge in professional activities, preparation for a comprehensive physics exam for masters.
Recommended or required reading and other learning resources/tools
1. P.A. Zyla et al. (Particle Data Group), Prog. Theor. Exp. Phys. 2020, 083C01 (2020) and 2021 update. Machine learning. 2. M. D. Schwartz. Modern Machine Learning and Particle Physics. /M. D. Schwartz //https://arxiv.org/abs/2103.12226v1 3. Antonia Creswell. Generative Adversarial Networks: An Overview. / A. Creswell, T. White, V. Dumoulin, K. Arulkumaran, B. Sengupta, A. A Bharath // https://arxiv.org/abs/1710.07035v1, 10.1109/MSP.2017.2765202 4. A. Butter. Generative Networks for LHC events. / A.Butter and T. Plehn // https://arxiv.org/abs/2008.08558v1 5. F. Psihas. A Review on Machine Learning for Neutrino Experiments /F. Psihas, M. Groh, Ch. Tunnell, K. Warburton.// Int. J. Mod. Phys. A. 2020. Vol.35. I.33. -P. 2043005, 10.1142/S0217751X20430058 6. J. Shlomi. Graph neural networks in particle physics. /J. Shlomi, P. Battaglia, J.-R. Vlimant//Machine Learning: Science and Technology - 2020. -Vol. 2, -N.2. -P. 021001. 10.1088/2632-2153/abbf9a
Planned learning activities and teaching methods
Seminars - 30 hours. Independent work - 60 hours.
Assessment methods and criteria
Semester assessment: (max / min) Survey during classes, preparation of reports on nanosystems physics - 60 points / 36 points The test is made in writing. The maximum number of points that can be obtained by a student during the test is 40. To obtain an overall positive grade in the discipline, the grade for the test may not be less than 24 points. A student is not admitted to the test if he / she scored less than 36 points during the semester.
Language of instruction
Ukrainian

Lecturers

This discipline is taught by the following teachers

Oleg Anatoliyovych Bezshyyko
Department of Nuclear Physics and High Energies
Faculty of Physics
Igor Mykolayovych Kadenko
Department of Nuclear Physics and High Energies
Faculty of Physics