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1.

図書

図書
H Nifenecker, O Meplan and S David
出版情報: Bristol : Institute of Physics Publishing, c2003  ix, 316 p. ; 25 cm
シリーズ名: Fundamental and applied nuclear physics series / series editors, R.R. Betts, W. Greiner and W.D. Hamilton
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目次情報: 続きを見る
Introduction / 1:
The energy issue / 2:
World energy perspectives / 2.1:
Energy consumptions / 2.1.1:
Fossil reserves / 2.1.2:
Greenhouse effect / 2.1.3:
Renewable energies / 2.2:
Solar energy / 2.2.1:
Biomass / 2.2.2:
Wind energy / 2.2.3:
Hydroelectricity / 2.2.4:
Nuclear energy / 2.3:
Standard reactors / 2.3.1:
Breeder reactors / 2.3.2:
Nuclear waste disposal options / 2.3.3:
Deployment of a breeder park / 2.3.4:
Costs / 2.4:
The possible role of accelerator driven subcritical reactors / 2.5:
Safety advantages of subcriticality / 2.5.1:
Use of additional neutrons / 2.5.2:
Elementary reactor theory / 3:
Interaction of neutrons with nuclei / 3.1:
Elementary processes / 3.1.1:
Properties of heavy nuclei / 3.1.2:
Neutron density, flux and reaction rates / 3.1.3:
Neutron propagation / 3.2:
Boltzmann equation / 3.2.1:
Integral form of the Boltzmann equation / 3.2.2:
Fick's law / 3.2.3:
Diffusion equation / 3.2.4:
Slowing down of neutrons / 3.2.5:
Neutron multiplying assemblies / 3.3:
Limiting values / 3.4:
Critical masses / 3.4.1:
Maximum flux / 3.4.2:
Reactor control / 3.5:
Delayed neutrons / 3.5.1:
Temperature dependence of the reactivity / 3.5.2:
Critical trip / 3.5.3:
Residual heat extraction / 3.5.4:
Fuel evolution / 3.6:
The Bateman equations / 3.6.1:
The long-term fuel evolutions / 3.6.2:
Basics of waste transmutation / 3.7:
Radiotoxicities / 3.7.1:
Neutron balance for transmutation and incineration / 3.7.2:
ADSR principles / 4:
Properties of the multiplying medium / 4.1:
Energy gain / 4.1.1:
Neutron balance / 4.1.2:
Neutron importance / 4.1.3:
Practical simulation methods / 5:
Neutron reaction data files / 5.1:
Determinstic methods / 5.2:
Monte Carlo codes / 5.3:
Deterministic versus Monte Carlo simulation codes / 5.3.1:
MCNP, a well validated Monte Carlo code / 5.3.2:
Physics in MCNP / 5.4:
Precision and variance reduction / 5.4.1:
MCNP in practice / 5.5:
Units / 5.5.1:
Input file structure / 5.5.3:
Examples / 5.6:
Reactivity calculation / 5.6.1:
Homogeneous versus heterogeneous cores / 5.6.2:
Subcritical core / 5.6.3:
Precision / 5.6.4:
Evolution constraint / 5.7:
Spatial flux / 5.7.2:
Special cross-section data / 5.7.3:
Time step between two MCNPs / 5.7.4:
The neutron source / 6:
Interaction of protons with matter / 6.1:
Electronic energy losses / 6.1.1:
Nuclear stopping / 6.1.2:
The nuclear cascade / 6.1.3:
Experimental tests of the INC models / 6.1.4:
State of the art of the simulation codes / 6.1.5:
Alternative primary neutron production / 6.2:
Deuteron induced neutron production / 6.2.1:
Muon catalysed fusion / 6.2.2:
Electron induced neutron production / 6.2.3:
Experimental determination of the energy gain / 6.3:
Two-stage neutron multipliers / 6.4:
High-intensity accelerators / 6.5:
State of the art of high-intensity accelerators / 6.5.1:
Requirements for ADSR accelerators / 6.5.2:
Perspectives for high-intensity accelerators for ADSRs / 6.5.3:
Examples of high-intensity accelerator concepts / 6.5.4:
ADSR kinetics / 7:
Reactivity evolutions / 8:
Long-term evolutions / 8.1:
Short-term reactivity excursions / 8.2:
Protactinium effect / 8.2.1:
Xenon effect / 8.2.2:
Temperature effect / 8.2.3:
Impact of reactivity excursions / 8.2.4:
Fuel reprocessing techniques / 9:
Basics of reprocessing / 9.1:
Wet processes / 9.2:
The purex process / 9.2.1:
Dry processes / 9.3:
Vaporization / 9.3.1:
Gas purge / 9.3.2:
Liquid-liquid extraction / 9.3.3:
Selective precipitation / 9.3.4:
Electrolysis / 9.3.5:
Generic properties of ADSRs / 10:
The homogeneous spherical reactor / 10.1:
General solution of the diffusion equation / 10.1.1:
The three-zone reactor / 10.1.2:
Model calculations / 10.1.3:
Parametric study of heterogeneous systems / 10.2:
Role of hybrid reactors in fuel cycles / 11:
The thorium-uranium cycle / 11.1:
Radiotoxicity / 11.1.1:
Breeding rates / 11.1.2:
Doubling time / 11.1.3:
Transition towards a [superscript 232]Th-based fuel from the PWR spent fuel, using a fast spectrum and solid fuel / 11.1.4:
Thorium cycle with thermal spectrum / 11.1.5:
Incineration / 11.2:
Plutonium incineration / 11.2.1:
Minor actinide incineration / 11.2.2:
Initial reactivity of MA fuels / 11.2.3:
Solid versus liquid fuels / 11.2.4:
The paradox of minor actinide fuels / 11.2.6:
Ground laying proposals / 12:
Solid fuel reactors / 12.1:
Lead cooled ADSR: the Rubbia proposal / 12.1.1:
Molten salt reactors / 12.2:
The Bowman proposal / 12.2.1:
The TIER concept / 12.2.2:
Cost estimates / 12.3:
Scenarios for the development of ADSRs / 13:
Experiments / 13.1:
The FEAT experiment / 13.1.1:
The MUSE experiment / 13.1.2:
Demonstrators / 13.2:
Japan / 13.2.1:
United States / 13.2.2:
Europe / 13.2.3:
Deep underground disposal of nuclear waste / Appendix I:
Model of an underground disposal site / I.1:
Radioelement diffusion in geological layers / I.1.2:
Physical model of diffusion in the clay layer / I.1.3:
Simplified solution of the diffusion problem through the clay layer / I.1.4:
Solubility as a limiting factor of the flow of radioactive nuclei / I.1.5:
Determining the dose to the population / I.2:
Some dose determination examples / I.2.1:
Full computation example of the dose at the outlet / I.2.2:
Accidental intrusion / I.3:
Drilled samples / I.3.1:
Using the well to draw drinking water / I.3.2:
Heat production and sizing of the storage site / I.4:
Schematic determination of the temperature distribution / I.4.1:
Geological hazard / I.4.2:
An underground laboratory. What for? / I.6:
Conclusion / I.7:
The Chernobyl accident and the RMBK reactors / Appendix II:
The RBMK-1000 reactor / II.1:
Events leading to the accident / II.2:
The accident / II.3:
Basics of accelerator physics / Appendix III:
Linear accelerators / III.1:
The Wideroe linear accelerator / III.1.1:
The Alvarez or drift tube linac (DTL) / III.1.2:
Phase stability / III.1.3:
Beam focusing / III.1.4:
The radio frequency quadrupole (RFQ) / III.1.5:
Cyclotrons / III.2:
Superconductive solutions / III.3:
Space charge limitations / III.4:
Bibliography
Index
Introduction / 1:
The energy issue / 2:
World energy perspectives / 2.1:
2.

図書

図書
John R. Lamarsh
出版情報: Reading, Mass. : Addison-Wesley Pub. Co., c1975  xii, 626 p. ; 25 cm
シリーズ名: Addison-Wesley series in nuclear science and engineering
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3.

図書

図書
John G. Yevick, editor. A. Amorosi, associate editor
出版情報: Cambridge ; London : M.I.T. Press, c1966  xviii, 754 p ; 27 cm
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4.

図書

図書
[by] Loren C. Schmid
出版情報: New York : Wiley-Interscience, c1971  xvii, 381 p ; 24 cm
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5.

図書

図書
Raymond L. Murray
出版情報: Englewood Cliffs, N.J. : Prentice-Hall, c1957  xi, 317 p. ; 24 cm
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6.

図書

図書
Samuel Glasstone & Alexander Sesonske
出版情報: New York, N.Y. ; Tokyo : Chapman & Hall, 1994  xiv, 486 p. ; 24 cm
シリーズ名: Nuclear reactor engineering / Samuel Glasstone & Alexander Sesonske ; v. 1
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7.

図書

図書
Samuel Glasstone & Alexander Sesonske
出版情報: New York, NY : Chapman & Hall
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8.

図書

図書
Samuel Glasstone & Alexander Sesonske
出版情報: New York, N.Y. ; Tokyo : Chapman & Hall, 1994  p. 487-852 ; 24 cm
シリーズ名: Nuclear reactor engineering / Samuel Glasstone & Alexander Sesonske ; v. 2
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9.

図書

図書
Alan M. Jacobs, Donald E. Kline [and] Forrest J. Remick
出版情報: Princeton, N.J. : Van Nostrand, c1960  viii, 262 p ; 24 cm
シリーズ名: Van Nostrand nuclear science series
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10.

図書

図書
by the staff of Argonne National Laboratory ; J. Barton Hoag, editor and contributor
出版情報: Princeton, N.J. : Van Nostrand, c1958  xv, 480 p. ; 23 cm
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