大葉大學圖書館 |

Ideal MHD[electronic resource] /

紀錄類型:	書目-電子資源 : Monograph/item
杜威分類號:	538.6
書名/作者:	Ideal MHD/ Jeffrey Freidberg.
作者:	Freidberg, Jeffrey
出版者:	Cambridge : : Cambridge University Press,, 2014.
面頁冊數:	xx, 722 p. : : ill., digital ;; 24 cm.
標題:	Magnetohydrodynamics - Mathematical models.
標題:	Fluid dynamics - Mathematical models.
標題:	Turbulence - Mathematical models.
標題:	High temperature plasmas.
標題:	Plasma (Ionized gases)
標題:	Fusion reactors.
ISBN:	9780511795046
ISBN:	9781107006256
內容註:	Machine generated contents note: 1. Introduction; 2. The ideal MHD model; 3. General properties of ideal MHD; 5. Equilibrium: one-dimensional configurations; 6. Equilibrium: two-dimensional configurations; 7. Equilibrium: three-dimensional configurations; 8. Stability: general considerations; 9. Alternate MHD models; 10. MHD stability comparison theorems; 11. Stability: one-dimensional configurations; 12. Stability: multi-dimensional configurations; Appendix A. Heuristic derivation of the kinetic equation; Appendix B. The Braginskii transport coefficients; Appendix C. Time derivatives in moving plasmas; Appendix D. The curvature vector; Appendix E. Overlap limit of the high b and Greene-Johnson stellarator models; Appendix F. General form for q(y); Appendix G. Natural boundary conditions; Appendix H. Upper and lower bounds on dQKIN.
摘要、提要註:	Comprehensive, self-contained, and clearly written, this successor to Ideal Magnetohydrodynamics (1987) describes the macroscopic equilibrium and stability of high temperature plasmas - the basic fuel for the development of fusion power. Now fully updated, this book discusses the underlying physical assumptions for three basic MHD models: ideal, kinetic, and double-adiabatic MHD. Included are detailed analyses of MHD equilibrium and stability, with a particular focus on three key configurations at the cutting-edge of fusion research: the tokamak, stellarator, and reversed field pinch. Other new topics include continuum damping, MHD stability comparison theorems, neoclassical transport in stellarators, and how quasi-omnigeneity, quasi-symmetry, and quasi-isodynamic constraints impact the design of optimized stellarators. Including full derivations of almost every important result, in-depth physical explanations throughout, and a large number of problem sets to help master the material, this is an exceptional resource for graduate students and researchers in plasma and fusion physics.
電子資源:	https://doi.org/10.1017/CBO9780511795046

Ideal MHD[electronic resource] /
Freidberg, Jeffrey

Ideal MHD[electronic resource] /Jeffrey Freidberg. - Cambridge :Cambridge University Press,2014. - xx, 722 p. :ill., digital ;24 cm.

Machine generated contents note: 1. Introduction; 2. The ideal MHD model; 3. General properties of ideal MHD; 5. Equilibrium: one-dimensional configurations; 6. Equilibrium: two-dimensional configurations; 7. Equilibrium: three-dimensional configurations; 8. Stability: general considerations; 9. Alternate MHD models; 10. MHD stability comparison theorems; 11. Stability: one-dimensional configurations; 12. Stability: multi-dimensional configurations; Appendix A. Heuristic derivation of the kinetic equation; Appendix B. The Braginskii transport coefficients; Appendix C. Time derivatives in moving plasmas; Appendix D. The curvature vector; Appendix E. Overlap limit of the high b and Greene-Johnson stellarator models; Appendix F. General form for q(y); Appendix G. Natural boundary conditions; Appendix H. Upper and lower bounds on dQKIN.

Comprehensive, self-contained, and clearly written, this successor to Ideal Magnetohydrodynamics (1987) describes the macroscopic equilibrium and stability of high temperature plasmas - the basic fuel for the development of fusion power. Now fully updated, this book discusses the underlying physical assumptions for three basic MHD models: ideal, kinetic, and double-adiabatic MHD. Included are detailed analyses of MHD equilibrium and stability, with a particular focus on three key configurations at the cutting-edge of fusion research: the tokamak, stellarator, and reversed field pinch. Other new topics include continuum damping, MHD stability comparison theorems, neoclassical transport in stellarators, and how quasi-omnigeneity, quasi-symmetry, and quasi-isodynamic constraints impact the design of optimized stellarators. Including full derivations of almost every important result, in-depth physical explanations throughout, and a large number of problem sets to help master the material, this is an exceptional resource for graduate students and researchers in plasma and fusion physics.

ISBN: 9780511795046Subjects--Topical Terms:

711618
Magnetohydrodynamics
--Mathematical models.

LC Class. No.: QC718.5.M36 / F74 2014

Dewey Class. No.: 538.6

Ideal MHD[electronic resource] /
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520 $a Comprehensive, self-contained, and clearly written, this successor to Ideal Magnetohydrodynamics (1987) describes the macroscopic equilibrium and stability of high temperature plasmas - the basic fuel for the development of fusion power. Now fully updated, this book discusses the underlying physical assumptions for three basic MHD models: ideal, kinetic, and double-adiabatic MHD. Included are detailed analyses of MHD equilibrium and stability, with a particular focus on three key configurations at the cutting-edge of fusion research: the tokamak, stellarator, and reversed field pinch. Other new topics include continuum damping, MHD stability comparison theorems, neoclassical transport in stellarators, and how quasi-omnigeneity, quasi-symmetry, and quasi-isodynamic constraints impact the design of optimized stellarators. Including full derivations of almost every important result, in-depth physical explanations throughout, and a large number of problem sets to help master the material, this is an exceptional resource for graduate students and researchers in plasma and fusion physics.
650 0 $a Magnetohydrodynamics $x Mathematical models. $3 711618
650 0 $a Fluid dynamics $x Mathematical models. $3 404564
650 0 $a Turbulence $x Mathematical models. $3 404021
650 0 $a High temperature plasmas. $3 602188
650 0 $a Plasma (Ionized gases) $3 196860
650 0 $a Fusion reactors. $3 635327
856 4 0 $u https://doi.org/10.1017/CBO9780511795046