CANCELED Radiation Physics Radiation Physics for Medical Physicists

Course content

The course is focused on the production and interaction of ionizing radiation with biological matter.

The course is divided into a theoretical part and an experimental part, each consisting of four weeks. The first part consists of lectures and theoretical exercises at NBI. The second part consists of four experimental exercises done at DTU, Risø.

The students will understand the sources of radiation, the different energy scales of the radiation and the matter which it traverses, and the ionization processes, which may cause damage to biological systems.

  • Sources of radiation and decay laws.
  • Classical and quantal scattering of charged particles, energy loss, stopping power and straggling of radiation in matter, the Bethe formula and the Bragg peak.
  • Photo-absorption, Compton scattering and pair production for gamma rays in matter.
  • Interaction of neutrons with matter.
Education

M.Sc. Physics

Learning outcome

Skills
After completing the course, the student should to receive the top grade be able to:

  • Describe the sources of natural radiation and radiation generated by technical means, that is radioactive nuclei, cosmic radiation, X-ray machines, particle accelerators and neutron sources.
  • Explain the basic exponential decay law, the basic algebra of decay chains, and Poisson statistics for counting of radiation.
  • Describe the interaction of charged particles with matter, and the ionization processes and their dependence with the velocity of the radiation, especially as evidenced by the Bragg peak
  • Differentiate between the various interaction processes of gamma rays with matter, photo-absorption, Compton scattering and pair production, and qualitatively discuss their relative importance for light versus heavy elements, and for small versus large gamma ray energy.
  • Describe the interaction of neutrons with matter, scattering, thermalization, absorption and subsequent decay.
  • Understand the basis for thermoluminescent dosimetry, carry out and describe dosimetry measurements in various geometries (experimental exercise).
  • Describe the scintillation detection equipment of gamma rays, and differentiate between the various features of gamma spectra in relation to photo-absorption and Compton scattering. (experimental exercise)
  • Explain the theory and applications of beta-spectroscopy, continuous spectra and conversion electrons.
  • Explain electron dose kernels and the Cole experiment (cf. Podgorsak)
  • Calculate and evaluate the external dose and exposure from a given source, including buildup factors in shielding.
  • Demonstrate - through the discussion of scientific papers - application of the concepts and terms introduced in the course.

 

Knowledge
The student obtains an understanding of the physical background for the interaction of ionizing radiation with matter, especially biological matter.

 

Competences
The course will enable the student to perform detailed calculations of energy depositions in matter for all forms of ionizing radiation.  The course will provide the student with examples of interdisciplinary practice, drawing on results and considerations from physics, chemistry, biology and medicine.

Lectures and theoretical exercises. Four mandatory whole-day experimental exercises at Risø ,DTU.

E.B. Podgorsak, “Radiation Physics for Medical Physicists”, Springer-Verlag 2006, plus scientific papers and reports.

ECTS
7,5 ECTS
Type of assessment
Written examination, 3 hours under invigilation
written exam, 3 hours with all aids allowed
Aid
All aids allowed
Marking scale
7-point grading scale
Censorship form
No external censorship
More internal examiners
Criteria for exam assessment

see skills

Single subject courses (day)

  • Category
  • Hours
  • Lectures
  • 24
  • Practical exercises
  • 32
  • Theory exercises
  • 16
  • Guidance
  • 12
  • Exam
  • 3
  • Preparation
  • 119
  • English
  • 206