Imaging gaseous detectors and their applications

Describing advanced detectors and their visualization and investigation techniques, this book presents the major applications in nuclear and high-energy physics, astrophysics, medicine and radiation measurements.

Auteur

Dr. Eugenio Nappi is Director of Research at the INFN (Italian Institute for Research in Nuclear Physics). Since the beginning of his career, he has had a keen interest in the experimental aspects of CERN's physics program of ultra-relativistic collisions of heavy ions at the SPS and subsequently, in the conception and development of the ALICE experiment at the LHC. He is the author and co-author of more than 200 papers published in international journals as well as member of the International Scientific Advisory and Organizing Committees in several conferences and workshops on nuclear physics instrumentation.

Prof. Vladimir Peskov is a chief scientist at the Institute for Chemical Physics Russian Academy of Sciences (RAS). He worked in the Physics Laboratory RAS led by P. L. Kapitza where he discovered and studied a new type of plasma instability. In 1986 he obtained an Associate Scientist position at CERN in G. Charpak's group and later spent most of his career working at various Scientific Institutions (CERN, Fermi National Laboratory, NASA and the Royal Institute of Technology, Sweden) on the instrumentation for high energy physics, astrophysics and medicine. He is the author and co-author of more than one hundred publications and twelve International Patents, member of the International Scientific Advisory and Organizing Committees in several conferences and workshops on instrumentation for high energy physics.

Texte du rabat

This authored title gives a comprehensive description of modern gaseous
detectors of photons and charged particles, a technology and devices
widely used in physics experiments and industrial applications. In the
last decade, a new generation of position-sensitive gaseous detectors
has appeared: the micropattern gaseous detectors, which are inspiring
and stimulating new directions in all the fields where imaging techniques
are exploited.

From the contents:
?? Imaging of photons and charged particles
?? Basic physics processes occurring in gaseous detectors
?? Traditional position-sensitive gaseous detectors and their historical development
?? MWPC era
?? Parallel Plate Avalanche Chambers and Resistive Plate Chambers
?? Micropattern gaseous detectors
?? Applications of imaging gaseous detectors

Contenu
I. Introduction
I.1. Why is it necessary to detect photons and charged particles?
(from the structure of the matter and universe to practical applications)
I.2. Principle of radiation interaction with gases
I.3. History of developments and traditional position-sensitive gaseous detectors:
a) Spark chambers
b) Multi-wire proportional chambers. Why multi-wire proportional chambers revolutionized the detector developments?
c) Parallel-plate chambers
d) Resistive plate chambers (RPCs)
e) Time-projection chambers
f) Gas scintillation detectors and light emission chambers
II. Operational Physics of Gaseous Detectors

1. Townsend avalanches
2. Proportional mode of operation
3. Physics of photon and ion feedbacks
4. Geiger mode of operation
5. Streamers and breakdowns
6. Maximum achievable gas gains and the Raether limit
7. Operation at very high counting rates and the cathode excitement effect
8. Optimization of gas mixtures for the needs of particular measurements or requirements.
   III. Recent Developments
   III.1.Photosensitive gaseous detectors
9. Multi-wire chambers filled with photosensitive gases
10. Multi-wire and parallel-plate chambers combined with solid photocathodes
    III.2. Micropattern gaseous detectors-a new revolution in the detector developments
11. Microstrip gas chambers
12. Microdot gas chambers
13. Microgap parallel-plate chambers and MICROMEGAS
14. Capillary plates, GEMs, GEMs with resistive electrodes
15. LEAK detector and other new designs of micropattern gaseous detectors
16. Operational physics of micropattern gaseous detectors
    a) What determines the maximum achievable gain in the micropattern gaseous detectors?
    b) Raether limit in the case of the micropattern detectors
    c) Cathode excitement effect
17. New possibilities in measurements offered by micropattern gaseous detectors
    a) Very high position resolution detectors
    b) Micropattern photo-detectors
    IV. Applications of Position-Sensitive Gaseous Detectors
18. High energy physics (latest applications of position gaseous detectors in high energy physics experiments for tracking, muon detection and Cherenkov light detection)
19. Astrophysics and search of dark matter (flight and ground experiments)
20. Plasma diagnostics
21. Medicine and biology (full body x-ray scanners, heart diagnostics, mammographic scanners, portal imaging devices for advanced radiotherapy, biological imaging devices, PETs (RPC and high pressure capillary tubes)
22. Industrial and homeland security (crystallographic industrial imaging devices, airport x-ray scanners, muon tomography, UV visualization; recent developments: Rn and Po monitors, detectors of flames and dangerous gases)
    V. Conclusions
    The role of gaseous detectors in the greatest scientific discoveries, important applications, their possible future and their place with respect to other position-sensitive detectors (solid state, vacuum, liquid?).