Astrophysics, chemistry, and condensed matter
著者
書誌事項
Astrophysics, chemistry, and condensed matter
(Treatise on heavy-ion science / edited by D. Allan Bromley, v. 6)
Plenum Press, c1985
大学図書館所蔵 全18件
  青森
  岩手
  宮城
  秋田
  山形
  福島
  茨城
  栃木
  群馬
  埼玉
  千葉
  東京
  神奈川
  新潟
  富山
  石川
  福井
  山梨
  長野
  岐阜
  静岡
  愛知
  三重
  滋賀
  京都
  大阪
  兵庫
  奈良
  和歌山
  鳥取
  島根
  岡山
  広島
  山口
  徳島
  香川
  愛媛
  高知
  福岡
  佐賀
  長崎
  熊本
  大分
  宮崎
  鹿児島
  沖縄
  韓国
  中国
  タイ
  イギリス
  ドイツ
  スイス
  フランス
  ベルギー
  オランダ
  スウェーデン
  ノルウェー
  アメリカ
注記
Includes bibliographies and index
内容説明・目次
目次
- 1. Heavy-Ion Reactions in Nuclear Astrophysics.- 1. Introduction.- 2. Nuclear Astrophysics.- 2.1. The Primeval Big Bang.- 2.2. Some Mathematical Preliminaries.- 2.3. Stellar Burning Processes.- 2.4. Carbon, Neon, and Oxygen Burning.- 2.5. Silicon Burning and Supernovas.- 2.6. 12C + 12C, 12C + 16O, and 16O +16O in Explosive Oxygen Burning.- 3. Measurement Techniques for Sub-Coulomb-Barrier Heavy-Ion Reactions.- 3.1. The Residual Radioactivity Method.- 3.2. Detection of Fusion Residues.- 3.3. Detection of the Emitted Particles.- 3.4. Gamma-Ray Measurements.- 3.5. The Elastic Scattering Method.- 3.6. The Effects of Resonances.- 4. Experimental Data.- 4.1. The 12C + 12C Reactions.- 4.2. The 12C + 16O Reactions.- 4.3. The 16O + 16O Reactions.- 5. Reaction Model Calculations.- 5.1. The Shapes of S(E) Curves.- 5.2. Transfer Reactions.- 5.3. Optical Model Fits for Heavy-Ion Reactions.- 5.4. The Optical Model Fit of Michaud.- 5.5. The Equivalent Square-Well Optical Potential of Michaud and Fowler.- 5.6. A Simple Coulomb Barrier Penetration Model.- 5.7. The IWBC Model.- 5.8. Resonances in the Excitation Function.- 6. Concluding Remarks.- Note Added in Proof.- References.- 2. Heavy Ions in Hot Atom Chemistry.- 1. Introduction.- 2. Chemical Reactions Promoted by Accelerated Ions.- 2.1. Early Studies.- 2.2. Improved Bombardment Techniques.- 2.3. Results.- 3. Heavy Ions from the Spontaneous Decay of Radioactive Precursors.- 3.1. ? Decay of Isolated Tritiated Species.- 3.2. Applications to Structural and Kinetic Studies.- 3.3. Multicharged Ions from Nuclear Transitions Leading to Inner-Shell Ionization.- 4. Collision-Induced Coulomb Explosion of Fast Molecular Ions as a Structural Probe.- References.- 3. The Stopping and Range of Ions in Matter.- Abstract.- 1. Introduction.- 2. Stopping Power Tables.- 2.1. 1958: The Whaling Table.- 2.2. 1970: The Northcliffe-Schilling Table.- 2.3. 1972: The Bichsel Table.- 2.4. 1974: Ziegler and Chu Tables.- 2.5. 1977: Andersen and Ziegler: H Tables.- 2.6. 1978: Ziegler: He Tables.- 2.7. 1980: Ziegler Energetic Ion Tables.- 2.8. The Current Accuracy of Stopping Tables.- 3. Range Tables.- 3.1. 1970: Northcliffe and Schilling, "Range and Stopping Power Tables".- 3.2. 1970: Johnson and Gibbons LSS Range Tables.- 3.3. 1975: Gibbons, Johnson, and Mylroie Range Tables.- 3.4. 1975: Brice and Winterbon Range Tables.- 3.5. 1981: Littmark and Ziegler, Energetic Ion Range Tables.- 4. Electronic Stopping of Ions.- 5. Interaction of a Particle with a Free Electron Gas.- 6. Nuclear Stopping of Ions.- 7. Range Theory.- References.- 4. Ion Implantation.- 1. Introduction.- 2. Dynamics.- 2.1. Energy Loss, Range, and Damage.- 2.2. Replacement Collisions.- 2.3. Collision Cascades.- 2.4. Sputtering.- 3. Metals.- 3.1. Dilute Alloys.- 3.2. Concentrated Alloys.- 4. Semiconductors (Si).- 4.1. Amorphous Silicon and Epitaxy.- 4.2. Supersaturation.- 5. Ion Beam Mixing.- References.- 5. Heavy-Ion Channeling.- 1. Introduction.- 2. Trajectories and Interaction Potentials.- 2.1. Planar Channeling.- 2.2. Hyperchanneling.- 3. Energy Loss in Channels.- 3.1. Screening Effects on Energy Loss.- 3.2. Higher-Order Corrections for Electronic Stopping of Heavy Ions.- 4. Charge Changing Collisions.- 4.1. Capture and Loss under Channeling Conditions.- 4.2. Radiative Electron Capture.- 4.3. Electron Capture and Loss to Continuum States (Convey Electron Production).- 5. Resonant Coherent Excitation.- References.- 6. The Electronic Polarization Induced in Solids Traversed by Fast Ions.- 1. Introduction.- 2. The Wake.- 2.1. Bohr's Model.- 2.2. The Electron-Gas Model.- 2.3. Fluctuations in the Wake.- 3. Experiments with Fast Molecular-Ion Beams.- 3.1. Stopping-Power Effects.- 3.2. High-Resolution Measurements of Fragment Momenta.- 3.3. Understanding the Ring Patterns.- Acknowledgments.- References.- 7. Erosion of Surfaces by Fast Heavy Ions.- 1. Introduction.- 2. Sputtering at Low Energies.- 3. Sputtering at High Energies.- 3.1. General Remarks.- 3.2. Possible Connections with Track Formation.- 3.3. Role of Target Strength.- 3.4. Role of Electrical Conductivity.- 3.5. Experiments with UF4 Targets.- 3.6. Thermal Model of High-Energy Sputtering.- 3.7. Alternative Mechanisms.- 3.8. Elaboration of the Zeroth-Order Thermal Model.- 4. Applications.- 5. Summary and Conclusions.- Acknowledgments.- References.- 8. Heavy-Ion Damage in Solids.- 1. Introduction.- 2. Low-Energy Irradiations (E < 5 keV).- 3. Medium-Energy Irradiations (5-200 keV).- 3.1. Models of Displacement Cascades.- 3.2. Direct Observation of Individual Displacement Cascades.- 3.3. Point Defect Clustering in Individual Cascades.- 3.4. Studies of Cascades in Nonmetals.- 3.5. High-Dose Irradiations.- 3.6. Radiation-Enhanced Diffusion and Solute Redistribution.- 4. High-Energy Irradiation (E > 200 keV).- 4.1. Study of the Primary Damage.- 4.2. Use of High-Energy Damage to Produce High Levels of Displacement Damage.- References.- 9. Analysis with Heavy Ions.- 1. Introduction.- 2. Nuclear Reaction Analysis of Hydrogen in Solids.- 2.1. Hydrogen Profiles of Lunar Material and the History of the Solar Wind.- 2.2. Hydrogen Surface Contaminations and the Containment of Ultracold Neutrons.- 2.3. Hydrogen in Thin Film High Technology Materials.- 3. Rutherford Backscattering Spectrometry.- 3.1. Principles and Applications of Rutherford Backscattering Spectrometry.- 3.2. Analysis of Ion Implanted Samples.- 3.3. Thin Film Analysis: Ion-Beam-Mixing Induced Silicide Formation.- 3.4. Analysis of Surfaces with Heavy-Ion Beams.- 4. Nuclear Recoil Analysis.- Acknowledgments.- References.- 10. Heavy-Ion-Induced Fusion Power.- 1. Introduction.- 1.1. Inertial Confinement Fusion.- 1.2. Driver Technologies.- 1.3. Power Production Requirements.- 2. Heavy-Ion Drivers.- 2.1. Basic Concepts.- 2.2. Reference Designs.- 2.3. Feasibility Constraints.- 2.4. Costs.- 3. Targets.- 3.1. Principles.- 3.2. Designs.- 4. Reactors.- 4.1. General Considerations.- 4.2. Examples.- 5. Prospects.- 5.1. Secrecy Problems.- 5.2. Development Programs.- 5.3. Overview.- Appendix A: Statement of USDOE on Declassification Actions Issued on September 4, 1980.- Appendix B: Excerpts from the Public Transcript of the May 3, 1979 Meeting of the USDOE Energy Research Advisory Board
- Testimony of Dr. John Foster, Reporting on the Conclusions of the ICF Review he Chaired in 1979.- References.
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