The aim of this book is to give a comprehensive treatment of the majority of important classical field theory from the mathematics perspective. The opening Part 1 gives the exposition of classical mechanics and special relativity that are based on the Hamiltonian approach and emphasizes the Hamiltonian action of the relevant Lie groups. Part 2 bridges classical mechanics and classical field theory. The authors develop all necessary tools: Lagrangian formulation of classical field theory, conservation laws, the Noether theorem, and Hamiltonian formulation. They present all necessary facts about jet bundles, multivariable calculus of variations, etc. Part 3 discusses gauge field theory: Maxwell's theory with the abelian structure group $U(1)$, and Yang-Mills theory with the structure group being semisimple compact Lie groups. For the convenience of the reader, the authors collect all necessary facts about connections and curvature in vector and principal bundles. In Part 4 the authors briefly discuss the theory of gravity, i.e., Einstein's general relativity. The goal here is to give a coherent mathematical exposition of the basic notions. After careful discussion of properties of the spacetime in general relativity and a standard derivation of Einstein's field equations with matter, the authors discuss the so-called Palatini formalism, an approach to Hilbert-Einstein action when 10 matrix elements of the metric tensor and 40 components of the symmetric Christoffel symbols are independent variables. They also briefly discuss Hamiltonian formalism for Einstein equations and their special solutions, with and without the cosmological constant. Each chapter in the book concludes with exercises aimed at developing deeper insights into topics discussed in the chapter. Also, each part concludes with a ""Notes and References"" chapter, which provides references to necessary mathematics background and physics sources.
Alexander A. Kirillov, Jr., Stony Brook University, New York. Leon A. Takhtajan, Stony Brook University, New York
Foundations of classical mechanics and special relativity; Lagrangian mechanics; Integrals of motion and Noether's threorem; Integrations of equations of motion; Hamiltonian formalism; Hamiltonian action and moment map; Hamiltonian systems with constraints; Special relativity; Relativistic particle; Spinors and Dirac operator; Notes and references; Basics of classical field theory; Lagrangian formulation of field theory; Conservation laws; Hamiltonian formualtion of classical field theory; Notes and references; Classical gauge theories; Maxwell's equations; Gauge fixing and Hamiltonian formlaism in electromagnetism; Connections and curvature; Yang-Mills theory; Chern-Simons theory; Notes and references; Theory of gravity; General relativity; Einstein equations; Hamiltonian formulation and exact solutions; Notes and references; Bibliography; Index