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E-raamat: Nuclear Methods in Science and Technology

(Russian Academy of Sciences, Moscow, Russia)
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The application of nuclear physics methods is now widespread throughout physics, chemistry, metallurgy, biology, clinical medicine, geology, and archaeology. Accelerators, reactors, and various instruments that have developed together with nuclear physics have often been found to offer the basis for increasingly productive and more sensitive analytical techniques.

Nuclear Methods in Science and Technology provides scientists and engineers with a clear understanding of the basic principles of nuclear methods and their potential for applications in a wide range of disciplines.

The first part of the book covers the major points of basic theory and experimental methods of nuclear physics, emphasizing concepts and simple models that give a feel for the behavior of real systems. Using many examples, the second part illustrates the extraordinary possibilities offered by nuclear methods. It covers the Mossbauer effect, slow neutron physics, activation analysis, radiography, nuclear geochronology, channeling effects, nuclear microprobe, and numerous other topics in modern applied nuclear physics. The book explores applications such as tomography, the use of short-lived isotopes in clinical diagnoses, and nuclear physics in ecology and agriculture. Where alternative nonnuclear analytical techniques are available, the author compares the relevant nuclear method, enabling readers to judge which technique may be most useful for them.

Complete with a bibliography and extensive reference list for readers who want to delve deeper into a particular topic, this book applies various methods of nuclear physics to a wide range of disciplines.

Arvustused

"Because of its encyclopedic breadth, but greater depth, this is a book suitable for a fast introduction or a refresher, perhaps to senior undergraduates or anyone whose research might benefit from nuclear methods. this book certainly has a place in a science library." -Australian & New Zealand Physicist

"A useful resource." -Choice

Preface xi(2)
Acknowledgements xiii
1 Nuclear structure
1(48)
1.1 Atoms, nuclei, particles and types of interaction
1(7)
1.2 Conservation laws
8(4)
1.3 Classification of hadrons: quarks
12(1)
1.4 Parameters of atomic, nuclei
23(8)
1.5 Nuclear models
31(18)
1.5.1 The liquid drop model: Weizsacker formula
31(3)
1.5.2 Shell model of a nucleus
34(6)
1.5.3 Excited nuclear states
40(9)
2 Natural and artificial radioactivity
49(39)
2.1 Laws of radioactivity
49(2)
2.2 Types of radioactive decays
51(25)
2.2.1 Alpha-decay
51(4)
2.2.2 Beta-decay
55(5)
2.2.3 Electroweak interaction
60(5)
2.2.4 Gama-radiation
65(4)
2.2.5 Spontaneous nuclear fission
69(5)
2.2.6 Exotic radioactivity
74(2)
2.3 Stability of heavy and superheavy elements
76(4)
2.4 Radionuclide engineering
80(8)
2.4.1 Radionuclide pacemaker
82(1)
2.4.2 Production and activation of short-lived radionuclides in support of biomedical applications 2.4.2 Production and activation of short-lived radionuclides in support of biomedical applications
82(2)
2.4.3 Nuclear power supplies in space
84(4)
3 Nuclear reactions
88(39)
3.1 Cross section of reaction
88(2)
3.2 Conservation laws in nuclear reactions
90(3)
3.3 Elastic scattering of slow particles incident on nuclei
93(7)
3.4 Qualitative estimations of nuclear reaction cross sections
100(5)
3.5 Decay of a compound nucleus
105(2)
3.6 Cross sections of nuclear reactions in the resonance region
107(2)
3.7 Characteristics of neutron reactions
109(3)
3.8 Origin of elements
112(15)
4 Uniformities in the passage of nuclear particles through matter
127(44)
4.1 The passage of heavy charged particles through matter
127(5)
4.2 Rutherford scattering
132(2)
4.3 Characteristic features of the passage of electrons and positrons through matter
134(10)
4.3.1 Bremsstrahlung
134(1)
4.3.2 Multiple scattering of electrons
135(2)
4.3.3 Slowing down of positrons
137(7)
4.4 Passage of electromagnetic radiation through matter
144(10)
4.4.1 Photoeffect
145(2)
4.4.2 Compton effect
147(5)
4.4.3 Pair formation
152(2)
4.4.4 General character of interactions of Gama-quanta with matter
154(1)
4.5 Neutron slowing down
154(4)
4.6 Channelling effect
158(7)
4.7 Cosmic rays
165(6)
5 Detectors of nuclear radiation
171(40)
5.1 Gaseous counters
171(6)
5.1.1 Ionization chambers
172(2)
5.1.2 Proportional counters
174(2)
5.1.3 Geiger-Muller counters
176(1)
5.2 Semiconductor detectors
177(5)
5.2.1 Advanced germanium Gama-detector systems
181(1)
5.3 Methods of neutron detection
182(2)
5.4 Track-etch detectors
184(2)
5.5 Scintillation Gama-spectrometry
186(8)
5.5.1 Bismuth germanate scintillation crystal
189(1)
5.5.2 Compton suppression detectors
190(4)
5.6 (XXXE, E) technique for identification of detected particles
194(1)
5.7 Position-sensitive detectors
195(9)
5.7.1 Gas detector PSDs
196(3)
5.7.2 Scintillation counters
199(2)
5.7.3 Semiconductor PSDs
201(3)
5.8 Time and amplitude measurement techniques
204(4)
5.9 Statistical character of nuclear events
208(3)
6 Slow neutron physics
211(47)
6.1 Neutron sources
212(8)
6.1.1 Radioactive neutron sources
212(1)
6.1.2 Neutron production with accelerators
213(2)
6.1.3 Nuclear reactor
215(2)
6.1.4 The spallation neutron source
217(3)
6.2 Neutron diffraction
220(22)
6.2.1 Experimental techniques
224(3)
6.2.2 Neutron optics based on capillaries
227(4)
6.2.3 Magnetic scattering
231(2)
6.2.4 Study of liquids
233(2)
6.2.5 Inelastic scattering
235(6)
6.2.6 Ultracold neutron experiments
241(1)
6.3 Small-angle scattering
242(10)
6.3.1 Theoretical description of SANS
243(5)
6.3.2 Study of voids and damage
248(2)
6.3.3 Polymers in the solid state
250(2)
6.4 Neutron interferometry
252(6)
7 Nuclear methods for analysis of substance structure and composition
258(47)
7.1 Activation analysis
259(3)
7.1.1 The activation equation
259(1)
7.1.2 Methods of activation analysis
260(2)
7.2 Photoactivation analysis
262(4)
7.2.1 Nitrogen in silicates
262(4)
7.2.2 Photoactivation analysis of rare-earth element alloys
266(1)
7.3 Neutron activation analysis
266(7)
7.3.1 Detection of toxic elements
269(1)
7.3.2 Neutron depth profiling
270(3)
7.4 X-ray fluorescence analysis
273(4)
7.4.1 XFA analysis of blood serum
275(1)
7.4.2 White lead in paintings for age determination
276(1)
7.4.3 In vivo XFA of the human body
276(1)
7.5 Ion beam analysis
277(15)
7.5.1 Charge particle activation analysis
280(2)
7.5.2 CPAA for a biokinetics study in humans
282(1)
7.5.3 Charged particle analysis of surface contamination
283(3)
7.5.4 Rutherford backscattering spectroscopy
286(6)
7.6 Nuclear microanalysis
292(2)
7.7 Determination of atom locations in crystals by channelling
294(11)
8 Nuclear imaging
305(33)
8.1 Nuclear methods of non-destructive testing
305(14)
8.1.1 Gamma radiography
305(4)
8.1.2 Digital radiography
309(3)
8.1.3 Neutron radiography
312(6)
8.1.4 Dynamic Gama and neutron radiography
318(1)
8.2 Surface radiography
319(3)
8.3 Neutron diffraction topography
322(2)
8.4 Soft x-ray microscopy
324(2)
8.5 Emission and transmission tomography
326(12)
8.5.1 Principle of tomography
328(1)
8.5.2 Differential tomography
329(2)
8.5.3 XRF tomography
331(1)
8.5.4 X-ray microtomography
332(2)
8.5.5 Positron emission tomography
334(4)
9 Mossbauer effect
338(21)
9.1 The physical basis of the Mossbauer effect
338(6)
9.2 Instrumentation
344(1)
9.3 Investigation of hyperfine, structure by the Mossbauer effect
345(1)
9.4 Examples of Gama-resonance spectroscopy
346(8)
9.4.1 Corrosion studies of iron and its alloys
347(1)
9.4.2 Biology
348(1)
9.4.3 Geology
349(2)
9.4.4 Superferromagnetic nanostructures
351(3)
9.5 Diffusion studies
354(5)
10 Nuclear physics, geology and archaeology
359(40)
10.1 Nuclear geochronology
360(3)
10.2 Radiocarbon dating
363(2)
10.3 Dating by single atom counting with accelerators (AMS spectroscopy)
365(5)
10.4 Neutrino geophysics
370(4)
10.5 Thermoluminescent dating
374(3)
10.6 Lead isotopes in geochronology and the age of the Earth
377(5)
10.7 Neutron and Gama-ray scattering measurements for subsurface geochemistry
382(11)
10.7.1 Gama-ray scattering for density and photoelectric absorption
383(4)
10.7.2 Neutron scattering for hydrogen content
387(2)
10.7.3 Neutron-induced Gama-ray spectroscopy
389(4)
10.8 Isotopic hydrology
393(6)
10.8.1 Earthquake prediction
394(1)
10.8.2 Radon mapping for locating geothermal energy sources
395(1)
10.8.3 Accelerator mass spectrometry in hydrology
396(3)
11 Radiation effects
399(30)
11.1 Radiation units
399(2)
11.2 Damage production in solids
401(5)
11.2.1 Photons
403(1)
11.2.2 Neutrons
404(1)
11.2.3 Electrons
405(1)
11.2.4 Ions
405(1)
11.2.5 Point defect accumulation
406(1)
11.3 Properties of damaged solids
406(4)
11.4 Radiation effects in dielectrics
410(3)
11.4.1 Organic materials
410(1)
11.4.2 Structural changes in glasses
411(2)
11.5 Radiobiological processes
413(1)
11.6 Radiation therapy
414(4)
11.6.1 Boron neutron-capture therapy
415(3)
11.7 Radiation processing
418(6)
11.7.1 Food irradiation
422(1)
11.7.2 Ecology
423(1)
11.8 Radiation protection and safety
424(5)
12 Practical applications of heavy ion and muon beams
429(22)
12.1 Heavy ions
429(11)
12.1.1 Ion implantation
429(1)
12.1.2 Modelling of radiation damage in reactor materials
430(2)
12.1.3 Nuclear track membranes
432(3)
12.1.4 Nano-orifices in a dielectric film
435(2)
12.1.5 Secondary structures on the base of nuclear filters
437(1)
12.1.6 Applications of NTM in medicine and biology
438(2)
12.2 Muons
440(11)
12.2.1 Muon spin rotation spectroscopy
441(5)
12.2.2 Mossbauer and XXXSR spectroscopy of high temperature superconductors
446(5)
Index 451
P L Kapitza Institute for Physical Problems, Russian Academy of Sciences, Moscow, University of Malaya, Kuala Lumpur
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