Note from June 29, 2020
Although we do not yet know how long the social distancing related to the Covid-19 pandemic will last, and regardless of the changes that had to be made in the evaluation of the June 2020 session in relation to what is provided for in this learning unit description, new learnig unit evaluation methods may still be adopted by the teachers; details of these methods have been - or will be - communicated to the students by the teachers, as soon as possible.
Although we do not yet know how long the social distancing related to the Covid-19 pandemic will last, and regardless of the changes that had to be made in the evaluation of the June 2020 session in relation to what is provided for in this learning unit description, new learnig unit evaluation methods may still be adopted by the teachers; details of these methods have been - or will be - communicated to the students by the teachers, as soon as possible.
4 credits
22.5 h + 7.5 h
Q2
Teacher(s)
Bruno Giacomo; Cortina Gil Eduardo; Delaere Christophe;
Language
English
Prerequisites
Having followed LPHYS2102 is an asset
Main themes
Advanced particle detectors ' Particle physics experiment design ' Triggering, data acquisition and computing systems ' Data reconstruction algorithms ' Advanced statistics ' Software tools for simulation in particle physics.
Content
1. Signal formation : general case.
2. Tracking detectors.
a. Large area counters: hodoscopes.
b. Magnetic spectrometers : magnets, resolution.
c. Gas position detectors : MWPC, drift detectors, jet chambers, TPCs, RPCs.
d. Solid state position detectors : silicon detectors, scintillation fiber detectors.
e. LAr TPCs. Double phase TPCs.
3. Calorimetry.
a. Electromagnetic calorimeters.
b. Hadronic calorimeters.
c. Low temperature calorimeters. Bolometers.
4. Particle identification.
a. Muon detectors.
b. Cerenkov detectors : threshold, differential, RICH.
c. TRD detectors.
d. Time of flight.
e. dE/dx.
5. Complex detector study : journal club like approach.
a. Collider : CMS, DELPHI.
b. Fixed target : NA62.
c. Astroparticle : AMS-02, Auger.
6. Auxiliary systems.
a. Low and high voltage systems.
b. Gas systems.
c. Cooling systems.
d. Mechanical supports.
e. Cabling.
7. Nuclear electronics.
8. Trigger and data acquisition systems.
9. Offline data processing systems.
10. Event reconstruction algorithms.
a. Tracking,
b. Vertexing.
c. Clustering.
d. Jets
11. Calibration and alignment techniques.
12. Statistical methods of data analysis.
13. Simulation of particle propagation in matter.
14. Projects concerning either the simulation of particle propagation in matter or real particle detection systems in the laboratory or a statistical analysis of data from a physics experiment.
2. Tracking detectors.
a. Large area counters: hodoscopes.
b. Magnetic spectrometers : magnets, resolution.
c. Gas position detectors : MWPC, drift detectors, jet chambers, TPCs, RPCs.
d. Solid state position detectors : silicon detectors, scintillation fiber detectors.
e. LAr TPCs. Double phase TPCs.
3. Calorimetry.
a. Electromagnetic calorimeters.
b. Hadronic calorimeters.
c. Low temperature calorimeters. Bolometers.
4. Particle identification.
a. Muon detectors.
b. Cerenkov detectors : threshold, differential, RICH.
c. TRD detectors.
d. Time of flight.
e. dE/dx.
5. Complex detector study : journal club like approach.
a. Collider : CMS, DELPHI.
b. Fixed target : NA62.
c. Astroparticle : AMS-02, Auger.
6. Auxiliary systems.
a. Low and high voltage systems.
b. Gas systems.
c. Cooling systems.
d. Mechanical supports.
e. Cabling.
7. Nuclear electronics.
8. Trigger and data acquisition systems.
9. Offline data processing systems.
10. Event reconstruction algorithms.
a. Tracking,
b. Vertexing.
c. Clustering.
d. Jets
11. Calibration and alignment techniques.
12. Statistical methods of data analysis.
13. Simulation of particle propagation in matter.
14. Projects concerning either the simulation of particle propagation in matter or real particle detection systems in the laboratory or a statistical analysis of data from a physics experiment.
Teaching methods
1. Theory classes and exercises.
- Lectures in auditorium.
- Resolution of problems .
2. Laboratory sessions (7.5h). Mandatory presence at the following laboratories :
3. Personal software project and report writing
- Lectures in auditorium.
- Resolution of problems .
2. Laboratory sessions (7.5h). Mandatory presence at the following laboratories :
- Large-area cosmic ray detector ;
- Silicon sensors characterization ;
- Construction of an RPC detector.
3. Personal software project and report writing
Evaluation methods
Evaluation of reports written by the students on projects concerning either the simulation of the particle propagation in matter or real systems for particle detection in a laboratory or a statistical analysis of data resulting from an experiment in physics. Evaluation of an oral interrogation on the projects and the subjects treated in the teaching unit.
Bibliography
C. Grupen, B. Schwartz, “Particle Detectors” (2nd edition).
D. Green, “The Physics of Particle Detectors”.
R. Fernow, “Introduction to Experimental Particle Physics”.
C. Leroy, P.G. Rancoita, “Principles of Radiation Interaction in Matter and Detection”.
S. Tavernier, “Experimental Techniques in Nuclear and Particle Physics”.
G. Cowan, “Statistical Data Analysis”, Oxford Science Publications.
D. Green, “The Physics of Particle Detectors”.
R. Fernow, “Introduction to Experimental Particle Physics”.
C. Leroy, P.G. Rancoita, “Principles of Radiation Interaction in Matter and Detection”.
S. Tavernier, “Experimental Techniques in Nuclear and Particle Physics”.
G. Cowan, “Statistical Data Analysis”, Oxford Science Publications.
Faculty or entity
PHYS