Thermonuclear reactions in stars (書籍, 2006) [University of Washington Libraries]
コンテンツへ移動
Thermonuclear reactions in stars 資料のプレビュー
閉じる資料のプレビュー

Thermonuclear reactions in stars

著者: C Iliadis
出版社: Weinheim : Wiley-VCH, 2006.
エディション/フォーマット:   紙書籍 : English
概要:

Thermonuclear reactions in stars is a major topic in the field of nuclear astrophysics, and deals with the topics of how precisely stars generate their energy through nuclear reactions, and how these  続きを読む

この資料のオンライン版を取得中… この資料のオンライン版を取得中…

オフラインで入手

配置場所と利用可否を確認中… 配置場所と利用可否を確認中…

WorldCat

世界の図書館の所蔵状況
この資料を所蔵している世界の図書館

詳細

ドキュメントの種類 書籍
すべての著者/寄与者: C Iliadis
ISBN: 3527406026 9783527406029
OCLC No.: 70677606
物理形態: approximately 450 pages : 160 illustrations (10 color)
コンテンツ: Preface. 1 Aspects of Nuclear Physics and Astrophysics. 1.1 History. 1.2 Nomenclature. 1.3 Solar System Abundances. 1.4 Astrophysical Aspects. 1.4.1 General Considerations. 1.4.2 Hertzsprung-Russell Diagram. 1.4.3 Stellar Evolution of Single Stars. 1.4.4 Binary Stars. 1.5 Masses, Binding Energies, Nuclear Reactions, and Related Topics. 1.5.1 Nuclear Mass and Binding Energy. 1.5.2 Energetics of Nuclear Reactions. 1.5.3 Atomic Mass and Mass Excess. 1.5.4 Number Abundance, Mass Fraction, and Mole Fraction. 1.5.5 Decay Constant, Mean Lifetime, and Half-Life. 1.6 Nuclear Shell Model. 1.6.1 Closed Shells and Magic Numbers. 1.6.2 Nuclear Structure and Nucleon Configuration. 1.7 Nuclear Excited States and Electromagnetic Transitions. 1.7.1 Energy, Angular Momentum, and Parity. 1.7.2 Transition Probabilities. 1.7.3 Branching Ratio and Mixing Ratio. 1.7.4 Gamma-Ray Transitions in a Stellar Plasma. 1.7.5 Isomeric States and the Case of <sup>26</sup>Al. 1.8 Weak Interaction. 1.8.1 Weak Interaction Processes. 1.8.2 Energetics. 1.8.3 Beta-Decay Probabilities. 1.8.4 Beta-Decays in a Stellar Plasma. 2 Nuclear Reactions. 2.1 Cross Sections. 2.2 Reciprocity Theorem. 2.3 Elastic Scattering and Method of Partial Waves. 2.3.1 General Aspects. 2.3.2 Relationship Between Differential Cross Section and Scattering Amplitude. 2.3.3 The Free Particle. 2.3.4 Turning the Potential On. 2.3.5 Scattering Amplitude and Elastic Scattering Cross Section. 2.3.6 Reaction Cross Section. 2.4 Scattering by Simple Potentials. 2.4.1 Square-Well Potential. 2.4.2 Square-Barrier Potential. 2.4.3 Transmission Through the Coulomb Barrier. 2.5 Theory of Resonances. 2.5.1 General Aspects. 2.5.2 Logarithmic Derivative, Phase Shift, and Cross Section. 2.5.3 Breit-Wigner Formulas. 2.5.4 Extension to Charged Particles and Arbitrary Values of Orbital Angular Momentum. 2.5.5 R-Matrix Theory. 2.5.6 Experimental Tests of the One-Level Breit-Wigner Formula. 2.5.7 Partial and Reduced Widths. 2.6 Continuum Theory. 2.7 Hauser-Feshbach Theory. 3 Thermonuclear Reactions. 3.1 Cross Sections and Reaction Rates. 3.1.1 Particle-Induced Reactions. 3.1.2 Photon-Induced Reactions. 3.1.3 Abundance Evolution. 3.1.4 Forward and Reverse Reactions. 3.1.5 Reaction Rates at Elevated Temperatures. 3.1.6 Reaction Rate Equilibria. 3.1.7 Nuclear Energy Generation. 3.2 Nonresonant and Resonant Thermonuclear Reaction Rates. 3.2.1 Nonresonant Reaction Rates for Charged-Particle-Induced Reactions. 3.2.2 Nonresonant Reaction Rates for Neutron-Induced Reactions. 3.2.3 Nonresonant Reaction Rates for Photon-Induced Reactions. 3.2.4 Narrow-Resonance Reaction Rates. 3.2.5 Broad-Resonance Reaction Rates. 3.2.6 Electron Screening. 3.2.7 Total Reaction Rates. 4 Nuclear Physics Experiments. 4.1 General Aspects. 4.1.1 Charged-Particle Beams. 4.1.2 Neutron Beams. 4.2 Interaction of Radiation with Matter. 4.2.1 Interactions of Heavy Charged Particles. 4.2.2 Interactions of Photons. 4.2.3 Interactions of Neutrons. 4.3 Targets and Related Equipment. 4.3.1 Backings. 4.3.2 Target Preparation. 4.3.3 Contaminants. 4.3.4 Target Chamber and Holder. 4.4 Radiation Detectors. 4.4.1 General Aspects. 4.4.2 Semiconductor Detectors. 4.4.3 Scintillation Detectors. 4.4.4 Proportional Counters. 4.4.5 Microchannel Plate Detectors. 4.5 Nuclear Spectroscopy. 4.5.1 Charged-Particle Spectroscopy. 4.5.2 Gamma-Ray Spectroscopy. 4.5.3 Neutron Spectroscopy. 4.6 Miscellaneous Experimental Techniques. 4.6.1 Radioactive Ion Beams. 4.6.2 Activation Method. 4.6.3 Time-of-Flight Technique. 4.7 Background Radiation. 4.7.1 General Aspects. 4.7.2 Background in Charged-Particle Detector Spectra. 4.7.3 Background in α-Ray Detector Spectra. 4.7.4 Background in Neutron Detector Spectra. 4.8 Yields and Cross Sections for Charged-Particle-Induced Reactions. 4.8.1 Nonresonant and Resonant Yields. 4.8.2 General Treatment of Yield Curves. 4.8.3 Measured Yield Curves and Excitation Functions. 4.8.4 Determination of Absolute Resonance Strengths and Cross Sections. 4.9 Transmissions, Yields, and Cross Sections for Neutron-Induced Reactions. 4.9.1 Resonance Transmission. 4.9.2 Resonant and Nonresonant Yields. 4.9.3 Effective Cross Section. 4.9.4 Measured Yields and Transmissions. 4.9.5 Relative and Absolute Cross Sections. 5 Nuclear Burning Stages and Processes. 5.1 Hydrostatic Hydrogen Burning. 5.1.1 pp Chains. 5.1.2 CNO Cycles. 5.1.3 Hydrostatic Hydrogen Burning Beyond the CNO Mass Region. 5.2 Explosive Hydrogen Burning. 5.2.1 Hot CNO Cycles. 5.2.2 Explosive Hydrogen Burning Beyond the CNO Mass Region. 5.3 Hydrostatic Helium Burning. 5.3.1 Helium-Burning Reactions. 5.3.2 Nucleosynthesis During Hydrostatic He Burning. 5.3.3 Other Helium-Burning Reactions. 5.4 Explosive Hydrogen-Helium Burning. 5.4.1 Breakout from the HCNO Cycles. 5.4.2 Network Calculations at Constant Temperature and Density. 5.4.3 Nucleosynthesis for Temperature-Density Profiles. 5.5 Advanced Burning Stages. 5.5.1 Carbon Burning. 5.5.2 Neon Burning. 5.5.3 Oxygen Burning. 5.5.4 Silicon Burning. 5.5.5 Nuclear Statistical Equilibrium and Freeze-Out. 5.6 Nucleosynthesis Beyond the Iron Peak. 5.6.1 The s-Process. 5.6.2 The r-Process. 5.6.3 The p-Process. 5.7 Origin of the Solar System Nuclides. Appendix. A Solutions of the Schrodinger Equation in Three Dimensions. A.1 Zero Orbital Angular Momentum and Constant Potential. A.2 Arbitrary Orbital Angular Momentum and Zero Potential. A.3 Arbitrary Orbital Angular Momentum and Coulomb Potential. B Quantum Mechanical Selection Rules. C Kinematics. C.1 Relationship of Kinematic Quantities in the Laboratory Coordinate System. C.2 Transformation Between Laboratory and Center-of-Mass Coordinate System. D Angular Correlations. D.1 General Aspects. D.2 Pure Radiations in a Two-Step Process. D.3 Mixed Radiations in a Two-Step Process. D.4 Three-Step Process with Unobserved Intermediate Radiation. D.5 Experimental Considerations. D.6 Concluding Remarks. E Constants, Data, Units, and Notation. E.1 Physical Constants and Data. E.2 Mathematical Expressions. E.3 Prefixes and Units. E.4 Physical Quantities. Color Plates. References. Index.
責任者: C. Iliadis.
注記を取得中… 注記を取得中…

レビュー

編集者のレビュー

出版社によるあらすじ

"This well-priced book's ability to both spark and feed readers' interest in astrophysics makes it an effective teaching resource and a valuable addition..." (CHOICE, December 2007)

 
ユーザーレビュー

タグ

まずはあなたから!

類似資料

リクエストの確認

あなたは既にこの資料をリクエストしている可能性があります。このリクエストを続行してよろしければ、OK を選択してください。

ウインドウを閉じる

WorldCatにログインしてください 

アカウントをお持ちではないですか?簡単に 無料アカウントを作成することができます。.