Nuclear physics: principles and applications
Gespeichert in:
| 1. Verfasser: | |
|---|---|
| Format: | Buch |
| Sprache: | English |
| Veröffentlicht: |
Chichester [u.a.]
Wiley
2008
|
| Ausgabe: | repr. |
| Schriftenreihe: | The Manchester physics series
|
| Schlagworte: | |
| Online-Zugang: | Inhaltsverzeichnis |
| Beschreibung: | XVI, 393 S. graph. Darst. |
| ISBN: | 9780471979364 0471979368 |
Internformat
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| 100 | 1 | |a Lilley, John S. |e Verfasser |4 aut | |
| 245 | 1 | 0 | |a Nuclear physics |b principles and applications |c J. S. Lilley |
| 250 | |a repr. | ||
| 264 | 1 | |a Chichester [u.a.] |b Wiley |c 2008 | |
| 300 | |a XVI, 393 S. |b graph. Darst. | ||
| 336 | |b txt |2 rdacontent | ||
| 337 | |b n |2 rdamedia | ||
| 338 | |b nc |2 rdacarrier | ||
| 490 | 0 | |a The Manchester physics series | |
| 650 | 4 | |a Nuclear physics |v Textbooks | |
| 650 | 0 | 7 | |a Kernphysik |0 (DE-588)4030340-8 |2 gnd |9 rswk-swf |
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| 999 | |a oai:aleph.bib-bvb.de:BVB01-016761463 | ||
Datensatz im Suchindex
| _version_ | 1804138051550576640 |
|---|---|
| adam_text | Contents
Flow diagram Inside front cover
Editors preface to the Manchester Physics Series
xiii
Author s preface
xv
PARTI PRINCIPLES
1
1
INTRODUCTION AND BASIC CONCEPTS
3
1.1
Introduction
3
1.2
Early Discoveries
4
1.3
Basic Facts and Definitions
6
1.3.1
The nucleus and its constituents
6
1.3.2
Isotopes, isotones and isobars
7
1.3.3
Nuclear mass and energy
7
1.4
Nuclear Potential and Energy Levels
9
1.4.1
Nucleón
states in a nucleus
9
1.4.2
Energy levels of nuclei
12
1.4.3
Occurrence and stability of nuclei
13
1.5
Radioactivity and Radioactive Decay
14
1.5.1
Alpha emission
14
1.5.2
Beta emission and electron capture
15
1.5.3
Gamma emission and internal conversion
17
1.5.4
Rate of radioactive decay
18
1.5.5
Radioactive decay chains
19
1.5.6
Radioactivity in the environment
21
1.5.7
Radioactive dating
22
1.6
Nuclear Collisions
22
1.6.1
Nomenclature
23
1.6.2
Probes
23
1.6.3
Cross section, differential cross section and reaction rate
24
1.6.4
Isotope production
25
1.6.5
Examples of nuclear reactions
27
Problems
1
32
vi
Contents
2
NUCLEAR
STRUCTURE
35
2.1
Introduction
35
2.2
Nuclear
Mass
36
2.2.1
The nuclear force
36
2.2.2
Semi-empirical mass formula
38
2.2.3
Nuclear stability
41
2.3
Nuclear Shell Model
45
2.3.1
Evidence for shell structure
45
2.3.2
Independent particle motion and the shell model
46
2.3.3
The spin-orbit potential
48
2.4
Single-Particle Features
50
2.4.1
Parity
50
2.4.2
Spectra of single-particle or single-hole nuclei
51
2.5
Collective States
54
2.5.1
Vibrational states
55
2.5.2
Deformed nuclei
58
2.5.3
Rotational states
59
2.5.4
Superdeformation
61
Problems
2
63
3
NUCLEAR INSTABILITY
65
3.1
Introduction
65
3.2
Gamma Emission
65
3.2.1
General features and selection rules
66
3.2.2
Transition rate
67
3.2.3
Internal conversion
73
3.3
Beta Decay
74
3.3.1
Beta-particle energy spectrum
75
3.3.2
Allowed transitions
77
3.3.3
Forbidden transitions
80
3.3.4
Comparison of
ß-decay
rates
82
3.3.5
Electron capture
83
3.4
Alpha Decay
84
3.4.1
Semi-classical theory of
α
decay
84
3.4.2
Alpha-particle energies and selection rules
88
3.4.3
Transuranic nuclei
89
Problems
3
90
4
NUCLEAR REACTIONS
93
4.1
Introduction
93
4.2
General Features of Nuclear Reactions
94
4.2.1
Energy spectra
94
4.2.2
Angular distributions
96
4.2.3
Cross sections
97
Contents
vii
4.3
Elastic
Scattering
and Nuclear Size
104
4.3.1
Electron scattering
104
4.3.2
Optical model for nuclear scattering
106
4.4
Direct Reactions
108
4.4.1
Angular momentum transfer in direct reactions
108
4.4.2
Selectivity in direct reactions
110
4.5
Compound Nucleus Reactions
113
4.5.1
Resonance in a compound nuclear reaction
114
4.5.2
Low-energy, neutron-induced fission
116
4.6
Heavy-Ion Reactions
117
4.6.1
Elastic scattering and direct reactions
118
4.6.2
Fusion
120
4.6.3
Deep inelastic reactions and limits to fusion
122
Problems
4 124
PART II INSTRUMENTATION AND APPLICATIONS
127
5
INTERACTION OF RADIATION WITH MATTER
129
5.1
Introduction
129
5.2
Heavy Charged Particles
129
5.2.1
Bethe-Bloch formula
130
5.2.2
Energy dependence
131
5.2.3
Bragg curve
132
5.2.4
Projectile dependence
133
5.2.5
Stopping medium dependence
134
5.3
Electrons
134
5.4
Gamma Rays
136
5.4.1
Photoelectric effect
138
5.4.2
Compton scattering
139
5.4.3
Pair production
140
5.4.4
Attenuation
141
5.5
Neutrons
142
5.5.1
Attenuation
143
5.5.2
Neutron moderation
144
Problems
5 148
6
DETECTORS AND INSTRUMENTATION
151
6.1
Introduction
151
6.2
Gas Detectors
152
6.2.1
Ionization chamber
152
6.2.2
Proportional counter
153
6.2.3
Geiger-Mueller counter
155
6.3
Scintillation Detectors
156
6.4
Semiconductor Detectors
158
6.4.1
The
p
-η
junction detector
160
viii Contents
6.4.2
The intrinsic detector
162
6.5
Detector Performance for Gamma Rays
162
6.5.1
Response to monoenergetic photons
162
6.5.2
Energy resolution
· 164
6.5.3
Peak-to-total ratio
165
6.6
Neutron Detectors
166
6.6.1
Slow-neutron detection
166
6.6.2
Fast-neutron detection
167
6.7
Particle Identification
168
6.7.1
E- AE counter telescope
168
6.7.2
Time of flight
168
6.7.3
Magnetic analysis
169
6.8
Accelerators
171
6.8.1
DC machines
171
6.8.2
AC machines
173
Problems
6 178
7
BIOLOGICAL EFFECTS OF RADIATION
181
7.1
Introduction
181
7.2
Initial Interactions
182
7.2.1
Direct and indirect physical damage
182
7.2.2
Indirect chemical damage
183
7.3
Dose, Dose Rate and Dose Distribution
185
7.3.1
Absorbed dose
185
7.3.2
Dose rate
185
7.3.3
Dose distribution and relative biological effectiveness
186
7.3.4
Equivalent dose
187
7.3.5
Effective dose
188
7.4
Damage to Critical Tissue
189
7.4.1
Complex molecules
189
7.4.2
Nucleic acids and damage repair
190
7.4.3
Modifying factors
192
7.5
Human Exposure to Radiation
195
7.5.1
Radiation in the environment
195
7.5.2
Evaluating the dose
198
7.6
Risk Assessment
200
7.6.1
Risk to occupationally exposed workers
201
Problems
7 202
8
INDUSTRIAL AND ANALYTICAL APPLICATIONS
205
8.1
Introduction
205
8.2
Industrial Uses
205
8.2.1
Tracing
205
8.2.2
Gauging
207
8.2.3
Material modification
208
Contents ix
8.2.4
Sterilization
209
8.2.5
Food preservation
210
8.2.6
Other applications
211
8.3
Neutron Activation Analysis
212
8.4
Rutherford Backscattering
215
8.5
Particle-Induced
Х
-Ray Emission
219
8.6
Accelerator Mass Spectrometry
223
8.7
Significance of Low-Level Counting
226
8.7.1
Null measurements with zero background
226
8.7.2
Low-level counting with finite background
227
Problems
8 229
9
NUCLEAR MEDICINE
233
9.1
Introduction
233
9.2
Projection Imaging:
Х
-Radiography and the Gamma Camera
234
9.2.1
Imaging with external radiation
234
9.2.2
Imaging with internal radiation
235
9.3
Computed Tomography
238
9.4
Positron Emission Tomography
242
9.5
Magnetic Resonance Imaging
245
9.5.1
Principles of
MRI
246
9.5.2
Excitation of a selected region
248
9.5.3
Readout and
MRI
image formation
248
9.5.4
Time variations of the signal
249
9.5.5
Functional
MRI
251
9.6
Radiation Therapy
253
9.6.1
Photons and electrons
253
9.6.2
Radionuclides
256
9.6.3
Neutron therapy
256
9.6.4
Heavy charged particles
257
Problems
9 259
10
POWER FROM FISSION
263
263
264
264
265
267
267
268
10.3
The Chain Reaction in a Thermal Fission Reactor
269
10.3.1
A nuclear power plant
269
10.3.2
The neutron cycle in a thermal reactor
271
10.3.3
Moderator
274
10.3.4
Optimizing the design
275
10.1
Introduction
10.2
Characteristics of Fission
10.2.1
Fission and fission products
10.2.2
Fission energy budget
10.2.3
Delayed neutrons
10.2.4
Neutron interactions
10.2.5
Breeder reactions
χ
Contents
10.4
The Finite Reactor
276
10.4.1
Diffusion
276
10.4.2
The continuity equation
277
10.4.3
Diffusion length
278
10.4.4
Reactor equation
279
10.4.5
Solving the reactor equation
281
10.5
Reactor Operation
283
10.5.1
Reactor power and fuel consumption
283
10.5.2
Reactor kinetics
284
10.5.3
Reactor poisoning
285
10.6
Commercial Thermal Reactors
287
10.6.1
Early gas-cooled reactors
287
10.6.2
Advanced gas-cooled reactor
(AGR)
288
10.6.3
Pressurized-water reactor
288
10.6.4
Boiling-water reactor
289
10.6.5
Heavy-water reactors
290
10.7
Future of Nuclear Fission Power
291
10.7.1
The breeder reactor
292
10.7.2
Accelerator-driven systems
294
Problems
10 295
11
THERMONUCLEAR FUSION
299
11.1 Introduction
299
11.2
Thermonuclear Reactions and Energy Production
300
11.2.1
Basic reactions and
Q
values
300
11.2.2
Cross sections
301
11.3
Fusion in a Hot Medium
302
11.3.1
Reaction rate
302
11.3.2
Performance criteria
304
11.4
Progress Towards Fusion Power
305
11.4.1
Magnetic confinement
306
11.4.2
Inertia! confinement fusion
311
11.5
Fusion in the Early Universe
313
11.6
Stellar Burning
315
11.6.1
Hydrogen burning
315
11.6.2
Helium burning
318
11.6.3
Beyond helium burning
319
11.7
Nucleosynthesis Beyond A
« 60 320
Problems
11 323
APPENDIX A: Useful Information
325
A.I Physical Constants and Derived Quantities
325
A.2 Masses and Energies
325
A.3 Conversion Factors
326
A.4 Useful Formulae
326
Contents xi
APPENDIX
В:
Partiele
in
a
Square
Well
329
APPENDIX
С:
Density of States and the Fermi Energy
333
C.I Density of States
333
C.2 Fermi Energy
335
APPENDIX D: Spherical Harmonics
337
APPENDIX E: Coulomb Scattering
341
APPENDIX F: Mass Excesses and Decay Properties of Nuclei
343
APPENDIX G: Answers and Hints to Problems
355
References
379
Bibliography
381
Index
385
|
| adam_txt |
Contents
Flow diagram Inside front cover
Editors' preface to the Manchester Physics Series
xiii
Author's preface
xv
PARTI PRINCIPLES
1
1
INTRODUCTION AND BASIC CONCEPTS
3
1.1
Introduction
3
1.2
Early Discoveries
4
1.3
Basic Facts and Definitions
6
1.3.1
The nucleus and its constituents
6
1.3.2
Isotopes, isotones and isobars
7
1.3.3
Nuclear mass and energy
7
1.4
Nuclear Potential and Energy Levels
9
1.4.1
Nucleón
states in a nucleus
9
1.4.2
Energy levels of nuclei
12
1.4.3
Occurrence and stability of nuclei
13
1.5
Radioactivity and Radioactive Decay
14
1.5.1
Alpha emission
14
1.5.2
Beta emission and electron capture
15
1.5.3
Gamma emission and internal conversion
17
1.5.4
Rate of radioactive decay
18
1.5.5
Radioactive decay chains
19
1.5.6
Radioactivity in the environment
21
1.5.7
Radioactive dating
22
1.6
Nuclear Collisions
22
1.6.1
Nomenclature
23
1.6.2
Probes
23
1.6.3
Cross section, differential cross section and reaction rate
24
1.6.4
Isotope production
25
1.6.5
Examples of nuclear reactions
27
Problems
1
32
vi
Contents
2
NUCLEAR
STRUCTURE
35
2.1
Introduction
35
2.2
Nuclear
Mass
36
2.2.1
The nuclear force
36
2.2.2
Semi-empirical mass formula
38
2.2.3
Nuclear stability
41
2.3
Nuclear Shell Model
45
2.3.1
Evidence for shell structure
45
2.3.2
Independent particle motion and the shell model
46
2.3.3
The spin-orbit potential
48
2.4
Single-Particle Features
50
2.4.1
Parity
50
2.4.2
Spectra of single-particle or single-hole nuclei
51
2.5
Collective States
54
2.5.1
Vibrational states
55
2.5.2
Deformed nuclei
58
2.5.3
Rotational states
59
2.5.4
Superdeformation
61
Problems
2
63
3
NUCLEAR INSTABILITY
65
3.1
Introduction
65
3.2
Gamma Emission
65
3.2.1
General features and selection rules
66
3.2.2
Transition rate
67
3.2.3
Internal conversion
73
3.3
Beta Decay
74
3.3.1
Beta-particle energy spectrum
75
3.3.2
Allowed transitions
77
3.3.3
Forbidden transitions
80
3.3.4
Comparison of
ß-decay
rates
82
3.3.5
Electron capture
83
3.4
Alpha Decay
84
3.4.1
Semi-classical theory of
α
decay
84
3.4.2
Alpha-particle energies and selection rules
88
3.4.3
Transuranic nuclei
89
Problems
3
90
4
NUCLEAR REACTIONS
93
4.1
Introduction
93
4.2
General Features of Nuclear Reactions
94
4.2.1
Energy spectra
94
4.2.2
Angular distributions
96
4.2.3
Cross sections
97
Contents
vii
4.3
Elastic
Scattering
and Nuclear Size
104
4.3.1
Electron scattering
104
4.3.2
Optical model for nuclear scattering
106
4.4
Direct Reactions
108
4.4.1
Angular momentum transfer in direct reactions
108
4.4.2
Selectivity in direct reactions
110
4.5
Compound Nucleus Reactions
113
4.5.1
Resonance in a compound nuclear reaction
114
4.5.2
Low-energy, neutron-induced fission
116
4.6
Heavy-Ion Reactions
117
4.6.1
Elastic scattering and direct reactions
118
4.6.2
Fusion
120
4.6.3
Deep inelastic reactions and limits to fusion
122
Problems
4 124
PART II INSTRUMENTATION AND APPLICATIONS
127
5
INTERACTION OF RADIATION WITH MATTER
129
5.1
Introduction
129
5.2
Heavy Charged Particles
129
5.2.1
Bethe-Bloch formula
130
5.2.2
Energy dependence
131
5.2.3
Bragg curve
132
5.2.4
Projectile dependence
133
5.2.5
Stopping medium dependence
134
5.3
Electrons
134
5.4
Gamma Rays
136
5.4.1
Photoelectric effect
138
5.4.2
Compton scattering
139
5.4.3
Pair production
140
5.4.4
Attenuation
141
5.5
Neutrons
142
5.5.1
Attenuation
143
5.5.2
Neutron moderation
144
Problems
5 148
6
DETECTORS AND INSTRUMENTATION
151
6.1
Introduction
151
6.2
Gas Detectors
152
6.2.1
Ionization chamber
152
6.2.2
Proportional counter
153
6.2.3
Geiger-Mueller counter
155
6.3
Scintillation Detectors
156
6.4
Semiconductor Detectors
158
6.4.1
The
p
-η
junction detector
160
viii Contents
6.4.2
The intrinsic detector
162
6.5
Detector Performance for Gamma Rays
162
6.5.1
Response to monoenergetic photons
162
6.5.2
Energy resolution
· 164
6.5.3
Peak-to-total ratio
165
6.6
Neutron Detectors
166
6.6.1
Slow-neutron detection
166
6.6.2
Fast-neutron detection
167
6.7
Particle Identification
168
6.7.1
E- AE counter telescope
168
6.7.2
Time of flight
168
6.7.3
Magnetic analysis
169
6.8
Accelerators
171
6.8.1
DC machines
171
6.8.2
AC machines
173
Problems
6 178
7
BIOLOGICAL EFFECTS OF RADIATION
181
7.1
Introduction
181
7.2
Initial Interactions
182
7.2.1
Direct and indirect physical damage
182
7.2.2
Indirect chemical damage
183
7.3
Dose, Dose Rate and Dose Distribution
185
7.3.1
Absorbed dose
185
7.3.2
Dose rate
185
7.3.3
Dose distribution and relative biological effectiveness
186
7.3.4
Equivalent dose
187
7.3.5
Effective dose
188
7.4
Damage to Critical Tissue
189
7.4.1
Complex molecules
189
7.4.2
Nucleic acids and damage repair
190
7.4.3
Modifying factors
192
7.5
Human Exposure to Radiation
195
7.5.1
Radiation in the environment
195
7.5.2
Evaluating the dose
198
7.6
Risk Assessment
200
7.6.1
Risk to occupationally exposed workers
201
Problems
7 202
8
INDUSTRIAL AND ANALYTICAL APPLICATIONS
205
8.1
Introduction
205
8.2
Industrial Uses
205
8.2.1
Tracing
205
8.2.2
Gauging
207
8.2.3
Material modification
208
Contents ix
8.2.4
Sterilization
209
8.2.5
Food preservation
210
8.2.6
Other applications
211
8.3
Neutron Activation Analysis
212
8.4
Rutherford Backscattering
215
8.5
Particle-Induced
Х
-Ray Emission
219
8.6
Accelerator Mass Spectrometry
223
8.7
Significance of Low-Level Counting
226
8.7.1
Null measurements with zero background
226
8.7.2
Low-level counting with finite background
227
Problems
8 229
9
NUCLEAR MEDICINE
233
9.1
Introduction
233
9.2
Projection Imaging:
Х
-Radiography and the Gamma Camera
234
9.2.1
Imaging with external radiation
234
9.2.2
Imaging with internal radiation
235
9.3
Computed Tomography
238
9.4
Positron Emission Tomography
242
9.5
Magnetic Resonance Imaging
245
9.5.1
Principles of
MRI
246
9.5.2
Excitation of a selected region
248
9.5.3
Readout and
MRI
image formation
248
9.5.4
Time variations of the signal
249
9.5.5
Functional
MRI
251
9.6
Radiation Therapy
253
9.6.1
Photons and electrons
253
9.6.2
Radionuclides
256
9.6.3
Neutron therapy
256
9.6.4
Heavy charged particles
257
Problems
9 259
10
POWER FROM FISSION
263
263
264
264
265
267
267
268
10.3
The Chain Reaction in a Thermal Fission Reactor
269
10.3.1
A nuclear power plant
269
10.3.2
The neutron cycle in a thermal reactor
271
10.3.3
Moderator
274
10.3.4
Optimizing the design
275
10.1
Introduction
10.2
Characteristics of Fission
10.2.1
Fission and fission products
10.2.2
Fission energy budget
10.2.3
Delayed neutrons
10.2.4
Neutron interactions
10.2.5
Breeder reactions
χ
Contents
10.4
The Finite Reactor
276
10.4.1
Diffusion
276
10.4.2
The continuity equation
277
10.4.3
Diffusion length
278
10.4.4
Reactor equation
279
10.4.5
Solving the reactor equation
281
10.5
Reactor Operation
283
10.5.1
Reactor power and fuel consumption
283
10.5.2
Reactor kinetics
284
10.5.3
Reactor poisoning
285
10.6
Commercial Thermal Reactors
287
10.6.1
Early gas-cooled reactors
287
10.6.2
Advanced gas-cooled reactor
(AGR)
288
10.6.3
Pressurized-water reactor
288
10.6.4
Boiling-water reactor
289
10.6.5
Heavy-water reactors
290
10.7
Future of Nuclear Fission Power
291
10.7.1
The breeder reactor
292
10.7.2
Accelerator-driven systems
294
Problems
10 295
11
THERMONUCLEAR FUSION
299
11.1 Introduction
299
11.2
Thermonuclear Reactions and Energy Production
300
11.2.1
Basic reactions and
Q
values
300
11.2.2
Cross sections
301
11.3
Fusion in a Hot Medium
302
11.3.1
Reaction rate
302
11.3.2
Performance criteria
304
11.4
Progress Towards Fusion Power
305
11.4.1
Magnetic confinement
306
11.4.2
Inertia! confinement fusion
311
11.5
Fusion in the Early Universe
313
11.6
Stellar Burning
315
11.6.1
Hydrogen burning
315
11.6.2
Helium burning
318
11.6.3
Beyond helium burning
319
11.7
Nucleosynthesis Beyond A
« 60 320
Problems
11 323
APPENDIX A: Useful Information
325
A.I Physical Constants and Derived Quantities
325
A.2 Masses and Energies
325
A.3 Conversion Factors
326
A.4 Useful Formulae
326
Contents xi
APPENDIX
В:
Partiele
in
a
Square
Well
329
APPENDIX
С:
Density of States and the Fermi Energy
333
C.I Density of States
333
C.2 Fermi Energy
335
APPENDIX D: Spherical Harmonics
337
APPENDIX E: Coulomb Scattering
341
APPENDIX F: Mass Excesses and Decay Properties of Nuclei
343
APPENDIX G: Answers and Hints to Problems
355
References
379
Bibliography
381
Index
385 |
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| index_date | 2024-07-02T22:11:24Z |
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| spelling | Lilley, John S. Verfasser aut Nuclear physics principles and applications J. S. Lilley repr. Chichester [u.a.] Wiley 2008 XVI, 393 S. graph. Darst. txt rdacontent n rdamedia nc rdacarrier The Manchester physics series Nuclear physics Textbooks Kernphysik (DE-588)4030340-8 gnd rswk-swf Kernphysik (DE-588)4030340-8 s DE-604 Digitalisierung UB Regensburg application/pdf http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=016761463&sequence=000002&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA Inhaltsverzeichnis |
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| title | Nuclear physics principles and applications |
| title_auth | Nuclear physics principles and applications |
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| title_full | Nuclear physics principles and applications J. S. Lilley |
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| title_short | Nuclear physics |
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| topic | Nuclear physics Textbooks Kernphysik (DE-588)4030340-8 gnd |
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