• Produktbild: The Skyrme Model
  • Produktbild: The Skyrme Model

The Skyrme Model Fundamentals Methods Applications

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Beschreibung

Produktdetails

Einband

Taschenbuch

Erscheinungsdatum

02.02.2012

Verlag

Springer Berlin

Seitenzahl

265

Maße (L/B/H)

23.5/15.5/1.6 cm

Gewicht

441 g

Auflage

Softcover reprint of the original 1st ed. 1993

Sprache

Englisch

ISBN

978-3-642-84672-4

Beschreibung

Produktdetails

Einband

Taschenbuch

Erscheinungsdatum

02.02.2012

Verlag

Springer Berlin

Seitenzahl

265

Maße (L/B/H)

23.5/15.5/1.6 cm

Gewicht

441 g

Auflage

Softcover reprint of the original 1st ed. 1993

Sprache

Englisch

ISBN

978-3-642-84672-4

Herstelleradresse

Springer-Verlag KG
Sachsenplatz 4-6
1201 Wien
AT

Email: GPSR Kontakt

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  • Produktbild: The Skyrme Model
  • Produktbild: The Skyrme Model
  • I Fundamentals.- 1. The Evolution of Skyrme’s Approach.- 1.1 The “Mesonic Fluid” Model.- 1.2 The Chiral Modification.- 1.3 The Two-Dimensional Simplified (sine-Gordon) Model.- 1.3.1 The Idea of Topological Charge.- 1.3.2 The Abelian Bosonization or Fermi-Bose Correspondence.- 1.4 The Baryon Model — Topological Skyrmions.- 1.4.1 The (3+1)-dimensional “Angular” Variables.- 1.4.2 The Topological Charge in the (3+1) Model.- 1.4.3. The Skyrme Model Dynamics.- 1.5 Skyrme’s Results and Conjectures.- 2. Elements of Field Theory with Topological Charges.- 2.1 Geometric Viewpoint on the Classical Field Theory.- 2.1.1 The Configuration Space.- 2.1.2 Homotopy as a Formalization of Dynamical Evolution.- 2.2 The Topological Classification of Solutions.- 2.2.1 Homotopy Classes of the sine-Gordon Model.- 2.2.2 The Fundamental and Higher Homotopy Groups.- 2.3 Isham’s Construction of Topological Charges.- 2.3.1 Cohomology — Homotopy Relationship in Brief.- 2.3.2 Derivation of Topological Charge in the Skyrme Model.- 2.4 Guiding Principles in the Choice of Model Lagrangians.- 2.4.1 Chirally Invariant Lagrangians.- 3. Topological Stability.- 3.1 Some General Remarks.- 3.2 The Hobart-Derrick Theorem.- 3.3 Soliton Stability and the Second Variation Structure of the Lyapunov Functional.- 3.3.1 The Lyapunov Stability of Solitons.- 3.3.2 The Generalized Hobart-Derrick Theorem.- 3.3.3 The Q-stability of Solitons.- 3.4 The Topological Stability of Skyrmions.- II Methods for the Study of Skyrmions.- 4. The Principle of Symmetric Criticality.- 4.1 Some Auxiliary Information.- 4.2 The Symmetry Group of the Skyrme Energy Functional.- 4.3 The Coleman-Palais Theorem.- 4.4 The Structure of Invariant Fields (Ansätze).- 5. Absolute Minimum of the Energy Functional.- 5.1 Method of Extending the Phase Space.- 5.2 The Spherical Rearrangement Method.- 5.3 Skyrmion as the Absolute Minimizer of the Energy.- 6. The Existence of Skyrmions.- 6.1 The Field Equations for Skyrmions.- 6.2 The Direct Method in the Calculus of Variations.- 6.3 An Outline of the Proof of the Skyrmion Existence.- 7. Multi-Baryon and Rotating Skyrmion States.- 7.1 The Problem of Bound States and Interaction Among Skyrmions.- 7.1.1 The Invariant Fields in Higher Homotopy Classes.- 7.2 Minima of the Energy Functional in Higher Homotopy Classes.- 7.3 The Rotating Skyrmion.- 8. Quantization of Skyrmions.- 8.1 Bogolubov’s Method of Collective Coordinates.- 8.2 Canonical Quantization of Skyrmions.- 8.3 The “Non-Rigid” Quantization of Skyrmions.- III Hadron Physics Applications.- 9. The Skyrme Model and QCD.- 9.1 Express Review of the QCD Present Status.- 9.2 1/N-Expansion.- 9.3 Effective Meson Theory from QCD.- 9.3.1 The Low-energy QCD Attributes.- 9.3.2 The Topological Charge as the Baryon Number.- 9.3.3 Effective Chiral Lagrangians from QCD.- 10. Skyrmion as a Fermion.- 10.1 The Finkelstein’s Double-Valued Functionals.- 10.2 The Charge-Monopole Multi-valued Action.- 10.3 The Wess-Zumino Term and Witten’s Realization of Skyrme’s Suggestion.- 10.3.1 The Wess-Zumino Term in Effective Chiral Lagrangian.- 10.3.2 Spin and Statistics of Skyrmions.- 11. Quantized SU(3) Skyrmions and Their Interactions.- 11.1 The SU(Z) Generalized Lagrangian in Terms of Collective Coordinates.- 11.1.1 The SU(3) Skyrme “Collective” Lagrangian.- 11.1.2 The Wess-Zumino Term for Collective Coordinates.- 11.1.3 The Symmetry Breaking Term.- 11.2 Quantization in the Presence of the Wess-Zumino Term.- 11.2.1 Canonical Quantization.- 11.2.2 Symmetries, Constraint and Spectrum.- 11.2.3 Static Observables and Mass Formulae.- 11.3 Skyrmions’ Interactions: Nuclear Forces and Nuclear Matter.- 11.3.1 The Skyrmion-Skyrmion Interaction and Nuclear Forces.- 11.3.2 The Meson-Baryon Interaction.- 11.3.3 The Skyrme Model and Nuclear Matter.- Concluding Remarks.- IV Appendices.- A. Chiral Symmetry.- A.1 Algebraic Aspects of Chiral Symmetry.- A.2 Geometric Aspects of Chiral Symmetry.- B. A Concise Account of Algebraic Topology.- B.1 Smooth Manifolds.- B.2 Tangent Spaces, Vector Fields and Lie Algebras.- B.3 Differential Forms.- B.4 Integration on Manifolds and De Rham Co-Homologies.- B.5 Fundamental Groups, Homotopy Groups and Some Other Topological Invariants.- C. Methods of Reduction.- C.1 Reduction to Static Field Configurations.- C.2 Reduction to G-Invariant Fields.- C.3 Spherical Rearrangement Technique: An Illustration.- D. Proofs of Stability and Existence Theorems.- D.1 Proof of Generalized Hobart-Derrick Theorem.- D.2 Existence of the Axially-Symmetric Solutions.- D.3 Existence of a Nonsingular Matrix.- E. Finkelstein-Williams’ Spinor Structures.- References.