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14 MeV Neutrons: Physics and Applications [Kõva köide]

  • Formaat: Hardback, 516 pages, kõrgus x laius: 234x156 mm, kaal: 861 g, 43 Tables, black and white; 254 Illustrations, black and white
  • Ilmumisaeg: 25-Aug-2015
  • Kirjastus: CRC Press Inc
  • ISBN-10: 1482238004
  • ISBN-13: 9781482238006
Teised raamatud teemal:
14 MeV Neutrons: Physics and ApplicationsSuurem pilt
  • Formaat: Hardback, 516 pages, kõrgus x laius: 234x156 mm, kaal: 861 g, 43 Tables, black and white; 254 Illustrations, black and white
  • Ilmumisaeg: 25-Aug-2015
  • Kirjastus: CRC Press Inc
  • ISBN-10: 1482238004
  • ISBN-13: 9781482238006
Teised raamatud teemal:
Püsilink: https://www.kriso.ee/db/9781482238006.html
Märksõnad:

Despite the often difficult and time-consuming effort of performing experiments with fast (14 MeV) neutrons, these neutrons can offer special insight into nucleus and other materials because of the absence of charge.14 MeV Neutrons: Physics and Applications explores fast neutrons in basic science and applications to problems in medicine, the environment, and security.

Drawing on his more than 50 years of experience working with 14 MeV neutrons, the author focuses on:

  • Sources of 14 MeV neutrons, including laboratory size accelerators, small and sealed tube generators, well logging sealed tube accelerators, neutron generators with detection of associated alpha particles, plasma devices, high flux sources, and laser-generated neutron sources
  • Nuclear reactions with 14 MeV neutrons, including measurements of energy spectra, angular distributions, and deductions of reaction mechanism
  • Nuclear reactions with three particles in the final state induced by neutrons and the identification of effects of final state interaction, quasi-free scattering, and charge-dependence of nuclear forces
  • Charged particle and neutron detection methods, particularly position-sensitive detectors
  • Industrial applications of nuclear analytical methods, especially in the metallurgy and coal industries
  • Quality assurance and quality control measures for nuclear analytical methods
  • Nuclear and atomic physics-based technology for combating illicit trafficking and terrorism
  • Medical applications, including radiography, radiotherapy, in vivo neutron activation analysis, boron neutron therapy, collimated neutron beams, and dosimetry

This book reflects the exciting developments in both fundamental nuclear physics and the application of fast neutrons to many practical problems. The book shows how 14 MeV neutrons are used in materials detection and analysis to effectively inspect large volumes in complex environments.

Preface xiii
Author xv
1 Introduction 1(16)
1.1 History: From Discovery to Present
1(2)
1.2 14 MeV Neutrons and Nuclear Weapons
3(4)
1.3 Nuclear Physics Probe
7(3)
1.3.1 Nuclear Data Centers
8(2)
1.4 Modern Applications
10(5)
1.4.1 In Fight against Terrorism
13(1)
1.4.2 In Control of Illicit Trafficking
14(1)
References
15(2)
2 Nuclear Reaction d+ t a+ n 17(18)
2.1 Properties of 3H(d,n)4He Nuclear Reaction
17(4)
2.2 D-T Fusion Reaction: Power Production
21(5)
2.3 Associated Alpha Particle-Tagged Neutron Beams
26(7)
References
33(2)
3 Sources of 14 MeV Neutrons 35(76)
3.1 Introduction
35(4)
3.2 Laboratory Size Accelerators
39(5)
3.3 Small and Sealed-Tube Neutron Generators
44(8)
3.3.1 VNIIA
46(2)
3.3.2 Thermo Electron
48(1)
3.3.3 NSD Fusion
48(1)
3.3.4 EADS Sodern
49(1)
3.3.5 Adelphi
49(3)
3.4 Well Logging Sealed-Tube Accelerators
52(7)
3.5 Neutron Generators with the Detection of Associated Alpha Particles
59(14)
3.5.1 Introduction
59(1)
3.5.2 API-120 Neutron Generator by THERMO
60(6)
3.5.3 VNIIA Neutron Generator
66(1)
3.5.4 SODERN Neutron Generators
67(6)
3.5.4.1 EURITRACK Generator
67(5)
3.5.4.2 Other SODERN Neutron Generators
72(1)
3.6 Plasma Devices
73(14)
3.6.1 Nonlinear Devices, Dense Plasma Focus
75(1)
3.6.2 NSD Neutron Generators
75(7)
3.6.3 Berkeley Laboratory Compact Neutron Generators
82(3)
3.6.4 Adelphi
85(2)
3.7 High Flux Sources
87(6)
3.8 Laser-Generated Nanosecond Pulsed Neutron Sources
93(2)
3.9 Calibrations of 14 MeV Neutron Generators
95(2)
3.10 New Developments
97(2)
3.10.1 Computer Chip-Shaped Neutron Source
97(2)
3.11 Safety and Regulations
99(7)
3.11.1 Introduction
99(1)
3.11.2 Technical Aspects of the Neutron Generator Safety
100(3)
3.11.2.1 Electrical Hazard
100(1)
3.11.2.2 Radiation Hazards
100(3)
3.11.3 General Rules
103(2)
3.11.3.1 Dealing with Electrical Hazards
104(1)
3.11.3.2 Dealing with Radiation Hazards
104(1)
3.11.4 Regulations
105(10)
3.11.4.1 Administrative Work before Buying a Neutron Generator
105(1)
3.11.4.2 Radiological Aspects
105(1)
3.11.4.3 Antiproliferation Rules That Apply for Any NG
105(1)
3.11.4.4 Regulations for Operation
106(1)
3.11.4.5 Regulations about NG's End of Life
106(1)
References
106(5)
4 Detectors 111(32)
4.1 Charged Particle Detection
111(4)
4.2 Scintillation Detectors
115(10)
4.2.1 Gamma Detection
119(6)
4.3 Neutron Detection, Neutron-Gamma Separation
125(9)
4.3.1 Directional Neutron Detectors
130(2)
4.3.2 New Developments in Neutron Detection
132(2)
4.4 Personal X-Ray, Gamma, and Neutron Detectors
134(4)
4.4.1 Innovative Physics
136(1)
4.4.2 Thermo Scientific
136(1)
4.4.3 Polimaster
137(1)
4.4.4 Mirion Technologies (MGP)
137(1)
4.4.5 Landauer Inc.
138(1)
4.4.6 Fuji Electric Co., Ltd.
138(1)
References
138(5)
5 Nuclear Reactions Induced by 14 MeV Neutrons 143(46)
5.1 Introduction
143(3)
5.2 Experimental Setup, Coincidence Measurements
146(1)
5.3 Nuclear Reactions on Light Nuclei
147(3)
5.4 Direct Reactions, Compound Nucleus Formation
150(20)
5.4.1 Elastic Scattering of 14 MeV Neutrons
152(2)
5.4.2 Inelastic Scattering of 14 MeV Neutrons
154(4)
5.4.3 (n, charged particle) Nuclear Reactions
158(10)
5.4.4 (n,2n) Reactions
168(2)
5.5 Activation Analysis: (n,p), (n,np), (n,a), (n,na), (n,n'y), (n,2n), (n,t), (n,3He) Reactions
170(3)
5.6 Fission Induced by 14 MeV Neutrons
173(1)
5.7 Neutron-Induced SEU
174(8)
References
182(7)
6 Fast Neutron Activation Analysis: An Analytical Method 189(68)
6.1 FNAA: Fundamentals and Applications
189(15)
6.2 QA/QC Measures, Reference Materials
204(4)
6.2.1 Explosive and CW Simulants
205(3)
6.3 Process Control of Industrial Production Processes
208(5)
6.4 Threat Material Detection with PFNA
213(12)
6.4.1 Explosives
213(9)
6.4.2 Active Detection of Special Nuclear Material
222(3)
6.5 Safety Issues
225(19)
6.5.1 Radiological Risks from Irradiation of Food in Neutron Inspection Systems
226(126)
6.5.1.1 Introduction
226(5)
6.5.1.2 Irradiation with Neutron Beams
231(1)
6.5.1.3 Definition of Safety for Food Irradiation with Neutrons
232(9)
6.5.1.4 Eritr@C System
241(3)
6.5.1.5 Conclusions
244(1)
6.6 Fusion with Other Methods
244(3)
References
247(10)
7 Applications of Tagged Neutron Beams 257(136)
7.1 Use of Tagged Neutron Beams
257(18)
7.2 Homeland Security Applications
275(10)
7.3 Detection of Threat Materials (Explosives, Drugs, and Dangerous Chemicals)
285(26)
7.4 Use of Tagged Neutron Beam for Sea Container Inspection, Transport Infrastructure Control
311(18)
7.5 Neutron Generators in Extreme Conditions
329(23)
7.6 More Objects to Be Inspected and Inspection Requirements
352(35)
7.6.1 Inspecting Underwater Ship's Hull
352(2)
7.6.2 Underwater Surveillance System for the Inspection of Strategic Coastal Energy Installations
354(17)
7.6.2.1 Introduction
354(2)
7.6.2.2 Objects to Be Inspected and Inspection Requirements
356(1)
7.6.2.3 Concrete in the Seawater
357(8)
7.6.2.4 Inspection/Testing of Unclean Structures
365(5)
7.6.2.5 Inspection/Testing of Clean Surfaces
370(1)
7.6.3 Small-Scale Variations in the Carbon/Oxygen Ratio in the Environment
371(4)
7.6.4 Carbon in Soil
375(10)
7.6.5 Diamond Detection in Kimberlite
385(2)
References
387(6)
8 Nuclear Reactions Logging 393(36)
8.1 Nuclear Well Logging
393(14)
8.1.1 Nuclear Well Logging in Hydrology
399(3)
8.1.2 Nuclear Mineral Logging
402(2)
8.1.3 Nuclear Well Logging in Oil Industry
404(3)
8.2 Logging with Pulsed Neutron Beam
407(8)
8.3 Carbon-Oxygen Log
415(1)
8.4 Small-Scale Variations in C/O Ratios
416(8)
References
424(5)
9 Medical Applications of 14 MeV Neutrons 429(52)
9.1 Introduction
429(1)
9.2 Biological and Medical Applications
429(2)
9.3 In Vivo Neutron Activation Analysis
431(4)
9.4 Neutron Radiography
435(5)
9.5 Fast Neutron Radiotherapy
440(7)
9.5.1 Boron-Neutron Capture Therapy
442(5)
9.6 Collimated Neutron Beams
447(21)
9.6.1 Slow Neutron Collimators
447(5)
9.6.2 Use of Collimated Fast Neutron Beam
452(16)
9.7 Quality Assurance Programs for Diagnostic Facilities
468(3)
9.8 Production of Radioisotopes Using Fast Neutrons
471(2)
9.9 Dosimetry
473(2)
References
475(6)
Index 481
Vladivoj Valkovi is a retired professor of physics, a fellow of the American Physical Society and Institute of Physics, and the founder and director of the Croatian-based company Analysis & Control Technologies Ltd. (A.C.T.d.o.o.), which implements environmental security projects. Dr. Valkovi has authored 13 books and more than 380 scientific and technical papers in many journals. His research interests include nuclear physics and the application of instrumentation and techniques to problems in biology, medicine, environmental research, and trace element analysis. He recently developed the idea of autonomous ship container inspection.