FYSS3550 Techniques for Nuclear and Accelerator-based Physics Experiments (10 cr)
Description
Interaction of radiation with matter
Principles, construction and operation of radiation detectors
Basics of signal processing
Production, separation and manipulation of (radioactive) ions
Methods to determine atomic masses
Methods in Nuclear Spectroscopy
Characterisation of materials with energetic ion beams
Basic mechanisms of radiation effects in electronics
Radiation environments governing the reliability of electronics
Learning outcomes
At the end of this course, students will be able to
operate various radiation detectors used in nuclear and accelerator-based physics experiments
construct measurement and coincidence circuits from modular electronics and use radiation detectors
recognise features of spectra from radiation detectors and relate them to the physical processes causing them
manipulate the trajectories of ions through a recoil separator and compare observations to ion-optical calculations
operate an ISOL-type mass separator and guide an ion beam through the system
characterise the composition of thin films of materials using ion-beam techniques
identify different radiation environments affecting electronic systems,
diagnose the radiation sensitivity of simple electronic components
differentiate the radiation induced error types in electronics
Description of prerequisites
Students enrolling to this course are expected to have completed the course Nuclear Physics (FYSS3300).
Study materials
Lecture slides and associated notes; relevant contemporary articles given by lecturers; independent literature searches.
Literature
- Juhani Kantele, Handbook of Nuclear Spectrometry
- William R. Leo, Techniques for Nuclear and Particle Physics Experiments
- Glenn F. Knoll, Radiation Detection and Measurement
Completion methods
Method 1
Teaching (10 cr)
Laboratory work, examination (home exam)