Radiation-matter interaction
- UE code SPHYM101
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Schedule
30 30Quarter 1
- ECTS Credits 6
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Language
Français
- Teacher
This lesson gives an overview of different type of interactions between radiations and matter. Radiations can be electromagnetic radiations or energetic particles. The matter is considered under its inert or biological form. The applications discussed in this lesson are related to particle detection (gamma rays and neutrons), the study of certain detectors associated to more fundamental physics, as well as medical diagnoses and cancer treatments using radiations.
Practical works are associated to each part (2 x 7h30).
Inert part (C. Stasser / J. Colaux)
Chapter 1: Interaction of charged particles in matter
Chapter 2: Interaction of neutral particles in matter
Chapter 3: Radiation detectors
Chapter 4: Examples
Biological part (S. Lucas)
Chapter 1: Introduction to radiation sources:
Chapter 2: Interaction of ionizing radiation (photons, charged particles, electrons, neutrons, …) with biological matter at different levels (molecules, cells, tissues, entire organism)
Chapter 3: Biomedical applications of radiations (medical imaging, nuclear medicine, radiotherapy, sterilization, ...)
Chapter 4: Control and radioprotection
Inert part (C. Stasser / J. Colaux, 15h-7h30)
Chapter 1: Interaction of charged particles in matter
Chapter 2: Interaction of neutral particles in matter
Chapter 3: Radiation detectors
Chapter 4: Examples
Biological part (S. Penninckx/ S. Lucas)
Chapter 1: Introduction to radiation sources:
Chapter 2: Interaction of ionizing radiation (photons, charged particles, electrons, neutrons, …) with biological matter at different levels (molecules, cells, tissues, entire organism)
Chapter 3: Biomedical applications of radiations (medical imaging, nuclear medicine, radiotherapy, sterilization, ...)
Chapter 4: Control and radioprotection
For the inert part (C. Stasser/J. Colaux): written exam during the session and a practical work to return before the written exam
For the biological part (S. Lucas): written exam
The final grade is the mean between the two parts.
The participation to the practical work is mandatory. Absence must be justified by a medical certificate sent to C. Stasser, S. Lucas and secretariat one day after the date of the practical work at the latest.
For a same academic year, dispenses can be allowed in some conditions under the decision of the teachers.
Introduction to experimental particle physics, RICHARD C. FERNOW
Principles of radiation interaction in matter and detection, Claude Leroy and Pier-Giorgio Rancoita
Training | Study programme | Block | Credits | Mandatory |
---|---|---|---|---|
Master 120 en sciences physiques, à finalité didactique | Standard | 0 | 6 | |
Master de spécialisation en nanotechnologie | Standard | 0 | 6 | |
Master 60 en sciences physiques | Standard | 0 | 6 | |
Master 120 en sciences physiques, à finalité approfondie | Standard | 0 | 6 | |
Master 120 en sciences physiques, à finalité spécialisée en physique du vivant | Standard | 0 | 6 | |
Master 120 en sciences physiques, à finalité spécialisée en physique et data | Standard | 0 | 6 | |
Master 120 en sciences physiques, à finalité didactique | Standard | 1 | 6 | |
Master de spécialisation en nanotechnologie | Standard | 1 | 6 | |
Master 60 en sciences physiques | Standard | 1 | 6 | |
Master 120 en sciences physiques, à finalité approfondie | Standard | 1 | 6 | |
Master 120 en sciences physiques, à finalité spécialisée en physique du vivant | Standard | 1 | 6 | |
Master 120 en sciences physiques, à finalité spécialisée en physique et data | Standard | 1 | 6 |