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Solitons, Instantons, and Twistors [Kõva köide]

4.33/5 (3 hinnangut Goodreads-ist)
(University of Cambridge, UK)
  • Formaat: Hardback, 374 pages, kõrgus x laius x paksus: 242x163x26 mm, kaal: 705 g, 35 illustrations
  • Sari: Oxford Graduate Texts in Mathematics 19
  • Ilmumisaeg: 10-Dec-2009
  • Kirjastus: Oxford University Press
  • ISBN-10: 0198570627
  • ISBN-13: 9780198570622
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Solitons, Instantons, and TwistorsSuurem pilt
  • Formaat: Hardback, 374 pages, kõrgus x laius x paksus: 242x163x26 mm, kaal: 705 g, 35 illustrations
  • Sari: Oxford Graduate Texts in Mathematics 19
  • Ilmumisaeg: 10-Dec-2009
  • Kirjastus: Oxford University Press
  • ISBN-10: 0198570627
  • ISBN-13: 9780198570622
Teised raamatud teemal:
Püsilink: https://www.kriso.ee/db/9780198570622.html
Märksõnad:
Most nonlinear differential equations arising in natural sciences admit chaotic behaviour and cannot be solved analytically. Integrable systems lie on the other extreme. They possess regular, stable, and well behaved solutions known as solitons and instantons. These solutions play important roles in pure and applied mathematics as well as in theoretical physics where they describe configurations topologically different from vacuum. While integrable equations in lower space-time dimensions can be solved using the inverse scattering transform, the higher-dimensional examples of anti-self-dual Yang-Mills and Einstein equations require twistor theory. Both techniques rely on an ability to represent nonlinear equations as compatibility conditions for overdetermined systems of linear differential equations.
The book provides a self-contained and accessible introduction to the subject. It starts with an introduction to integrability of ordinary and partial differential equations. Subsequent chapters explore symmetry analysis, gauge theory, gravitational instantons, twistor transforms, and anti-self-duality equations. The three appendices cover basic differential geometry, complex manifold theory, and the exterior differential system.

Most nonlinear differential equations arising in natural sciences admit chaotic behavior and cannot be solved analytically. Integrable systems lie on the other extreme. They possess regular, stable, and well behaved solutions known as solitons and instantons. These solutions play important roles in pure and applied mathematics as well as in theoretical physics where they describe configurations topologically different from vacuum. While integrable equations in lower space-time dimensions can be solved using the inverse scattering transform, the higher-dimensional examples of anti-self-dual Yang-Mills and Einstein equations require twistor theory. Both techniques rely on an ability to represent nonlinear equations as compatibility conditions for overdetermined systems of linear differential equations.

The book provides a self-contained and accessible introduction to the subject. It starts with an introduction to integrability of ordinary and partial differential equations. Subsequent chapters explore symmetry analysis, gauge theory, gravitational instantons, twistor transforms, and anti-self-duality equations. The three appendices cover basic differential geometry, complex manifold theory, and the exterior differential system.

Arvustused

My view is that the book is a success. I have no hesitation in recommending the book as a textbook/reference for advanced undergraduates (Mmath or other masters level), and for researchers as well. It is also very valuable as a crossover book: showing researchers in other disciplines how some of this new theory motivated by cosmology can be introduced into other areas such as fluid mechanics. * Professor Thomas J. Bridges, Contemporary Physics * As an introduction to an exciting area of research, this book is excellent because it is not only accessible but self contained. A wonderful feature of the book is the clear and informative explanation of the topics and the wealth of examples. The presentation style of the book means that it is accessible to readers ranging from advanced undergraduates doing research to experts. It would be an excellent textbook for a course at the advanced undergraduate level or graduate level in either mathematics or physics. This book will become a standard on the subject. The typesetting of the book is very clean, with nicely sized fonts and clean uniform notation. It includes 35 illustrations which helpfully illustrated text. It is my pleasure to highly recommend it to anyone from an advanced undergraduate to a researcher in the fields covered. * Donald M Witt, Classical and Quantum Gravity * The author has done a remarkable job of weaving these topics together in an engaging and readable book...my view is that the book is a success. I have no hesitation in recommending the book as a textbook/reference for advanced undergraduates (Mmath or other masters level), and for researchers as well. * Professor Thomas J. Bridges, Contemporary Physics *

List of Figures
xii
List of Abbreviations
xiii
Integrability in classical mechanics
1(19)
Hamiltonian formalism
1(3)
Integrability and action-angle variables
4(10)
Poisson structures
14(6)
Soliton equations and the inverse scattering transform
20(23)
The history of two examples
20(5)
A physical derivation of KdV
21(3)
Backlund transformations for the Sine-Gordon equation
24(1)
Inverse scattering transform for KdV
25(8)
Direct scattering
28(1)
Properties of the scattering data
29(1)
Inverse scattering
30(1)
Lax formulation
31(1)
Evolution of the scattering data
32(1)
Reflectionless potentials and solitons
33(10)
One-soliton solution
34(1)
N-soliton solution
35(1)
Two-soliton asymptotics
36(7)
Hamiltonian formalism and zero-curvature representation
43(21)
First integrals
43(3)
Hamiltonian formalism
46(2)
Bi-Hamiltonian systems
46(2)
Zero-curvature representation
48(8)
Riemann-Hilbert problem
50(2)
Dressing method
52(2)
From Lax representation to zero curvature
54(2)
Hierarchies and finite-gap solutions
56(8)
Lie symmetries and reductions
64(21)
Lie groups and Lie algebras
64(3)
Vector fields and one-parameter groups of transformations
67(4)
Symmetries of differential equations
71(7)
How to find symmetries
74(1)
Prolongation formulae
75(3)
Painleve equations
78(7)
Painleve test
82(3)
Lagrangian formalism and field theory
85(20)
A variational principle
85(5)
Legendre transform
87(1)
Symplectic structures
88(1)
Solution space
89(1)
Field theory
90(3)
Solution space and the geodesic approximation
92(1)
Scalar kinks
93(7)
Topology and Bogomolny equations
96(2)
Higher dimensions and a scaling argument
98(1)
Homotopy in field theory
99(1)
Sigma model lumps
100(5)
Gauge field theory
105(24)
Gauge potential and Higgs field
106(4)
Scaling argument
108(1)
Principal bundles
109(1)
Dirac monopole and flux quantization
110(4)
Hopf fibration
112(2)
Non-abelian monopoles
114(5)
Topology of monopoles
115(1)
Bogomolny-Prasad-Sommerfeld (BPS) limit
116(3)
Yang-Mills equations and instantons
119(10)
Chern and Chern-Simons forms
120(2)
Minimal action solutions and the anti-self-duality condition
122(1)
Ansatz for ASD fields
123(1)
Gradient flow and classical mechanics
124(5)
Integrability of ASDYM and twistor theory
129(20)
Lax pair
129(4)
Geometric interpretation
132(1)
Twistor correspondence
133(16)
History and motivation
133(4)
Spinor notation
137(2)
Twistor space
139(2)
Penrose-Ward correspondence
141(8)
Symmetry reductions and the integrable chiral model
149(42)
Reductions to integrable equations
149(5)
Integrable chiral model
154(37)
Soliton solutions
157(8)
Lagrangian formulation
165(3)
Energy quantization of time-dependent unitons
168(5)
Moduli space dynamics
173(8)
Mini-twistors
181(10)
Gravitational instantons
191(38)
Examples of gravitational instantons
191(4)
Anti-self-duality in Riemannian geometry
195(7)
Two-component spinors in Riemannian signature
198(4)
Hyper-Kahler metrics
202(4)
Multi-centred gravitational instantons
206(6)
Belinskii-Gibbons-Page-Pope class
210(2)
Other gravitational instantons
212(4)
Compact gravitational instantons and K3
215(1)
Einstein-Maxwell gravitational instantons
216(5)
Kaluza-Klein monopoles
221(8)
Kaluza-Klein solitons from Einstein-Maxwell instantons
222(4)
Solitons in higher dimensions
226(3)
Anti-self-dual conformal structures
229(58)
α-surfaces and anti-self-duality
230(1)
Curvature restrictions and their Lax pairs
231(15)
Hyper-Hermitian structures
232(2)
ASD Kahler structures
234(2)
Null-Kahler structures
236(1)
ASD Einstein structures
237(1)
Hyper-Kahler structures and heavenly equations
238(8)
Symmetries
246(16)
Einstein-Weyl geometry
246(7)
Null symmetries and projective structures
253(3)
Dispersionless integrable systems
256(6)
ASD conformal structures in neutral signature
262(3)
Conformal compactification
263(1)
Curved examples
263(2)
Twistor theory
265(22)
Curvature restrictions
270(2)
ASD Ricci-flat metrics
272(11)
Twistor theory and symmetries
283(4)
Appendix A: Manifolds and topology
287(13)
Lie groups
290(4)
Degree of a map and homotopy
294(6)
Homotopy
296(2)
Hermitian projectors
298(2)
Appendix B: Complex analysis
300(10)
Complex manifolds
301(2)
Holomorphic vector bundles and their sections
303(4)
Cech cohomology
307(3)
Deformation theory
308(2)
Appendix C: Overdetermined PDEs
310(34)
Introduction
310(4)
Exterior differential system and Frobenius theorem
314(6)
Involutivity
320(4)
Prolongation
324(8)
Differential invariants
326(6)
Method of characteristics
332(3)
Cartan-Kahler theorem
335(9)
References 344(11)
Index 355
Maciej Dunajski read physics in Lodz, Poland and received a PhD in mathematics from Oxford University where he held a Senior Scholarship at Merton College. After spending four years as a lecturer in the Mathematical Institute in Oxford where he was a member of Roger Penrose's research group, he moved to Cambridge, where holds a Fellowship and lectureship at Clare College and a Newton Trust Lectureship at the Department of Applied Mathematics and Theoretical Physics. Dunajski specialises in twistor theory and differential geometric approaches to integrability and solitons. He is married with two sons.