| General Preface | p. ix |
| Preface to Volume I | p. xi |
| Acknowledgements | p. xv |
| Maxwell Fields: General Theory | |
| The Rudiments of Abstract Differential Geometry | p. 3 |
| The Differential Setting | p. 3 |
| Logarithmic Derivation | p. 7 |
| A-Connections | p. 8 |
| The Classical Case | p. 10 |
| Local Definition of an A-Connection | p. 13 |
| Gauge Transformation | p. 18 |
| Induced A-Connections | p. 20 |
| Existence of A-Connections. Criteria of Existence | p. 27 |
| The Space of A-Connections | p. 30 |
| Related A-Connections. Moduli Space of A-Connections | p. 33 |
| Moduli Space | p. 34 |
| Curvature | p. 41 |
| Local Form of the Curvature | p. 44 |
| Transformation Law of Field Strength (Curvature) | p. 46 |
| Fundamental Identities of the Curvature (Continued). Torsion | p. 48 |
| Pullback of Curvature | p. 52 |
| Torsion | p. 53 |
| A-Connections Compatible with A-Metrics | p. 54 |
| Hermitian A-Connections | p. 56 |
| Matrices of A-Metrics | p. 58 |
| Kahler A-Metrics | p. 61 |
| Einstein A-Metrics | p. 62 |
| Lorentz A-Metrics | p. 63 |
| The Hodge *-Operator. Volume Form | p. 64 |
| Elementary Particles: Sheaf-Theoretic Classification, by Spin-Structure, According to Selesnick's Correspondence Principle | p. 69 |
| Preliminaries. Basic Notions | p. 69 |
| Classification of Elementary Particles, Through Vector Sheaves, According to Their Spin-Structures | p. 71 |
| Standard Classification of Elementary Particles by Spin Number | p. 71 |
| Classification of Elementary Particles Through Module-Structures (a la Selesnick) | p. 73 |
| Quantum State Modules | p. 74 |
| Free Bosons and Fermions in Terms of Finitely Generated Projective Modules | p. 79 |
| Finitely Generated Projective Modules and Vector Bundles (Serre-Swan Theory) | p. 81 |
| Vector Sheaves and Elementary Particles (Continued: Selesnick's Correspondence) | p. 84 |
| Smooth (C[superscript infinity]-) Case | p. 89 |
| Cohomological Classification of Elementary Particles | p. 91 |
| Vector Sheaves | p. 92 |
| Line Sheaves | p. 95 |
| Elementary Particles | p. 97 |
| Elementary Particles as Principal Sheaves | p. 98 |
| Principal Sheaves | p. 100 |
| Vector Sheaves Associated with Principal Sheaves and Physical Interpretation | p. 102 |
| Physical Applications | p. 109 |
| Interacting Particles | p. 110 |
| Electromagnetism | p. 113 |
| The Electromagnetic Field. The Maxwell Category | p. 114 |
| Characterization of the Maxwell Group Through Local Data | p. 118 |
| Local Characterization of Maxwell Fields | p. 120 |
| Local Characterization of (Gauge) Equivalent Maxwell Fields | p. 125 |
| A Natural Fibration | p. 128 |
| The Image of (the Natural Fibration) [tau] | p. 130 |
| Weil's Integrality Theorem (Again) | p. 132 |
| The Image of the Map [tau] (Continued) | p. 138 |
| Cohomology Class Associated with the Field Strength of a Maxwell Field (Continued) | p. 142 |
| The Fibration [tau] as a Group Morphism | p. 147 |
| Action of H[superscript 1] (X, C[Characters not reproducible]) on the Maxwell Group [Phi][Characters not reproducible](X)[superscript nabla] | p. 152 |
| Freeness of the Action of H[superscript 1](X, C[Characters not reproducible]) on the Maxwell Group | p. 154 |
| Transitivity of the Action of H[superscript 1](X, C[Characters not reproducible]) on the Maxwell Group | p. 157 |
| [Phi][Characters not reproducible](X)[Characters not reproducible] as a Principal Homogeneous Space | p. 164 |
| The Hermitian Counterpart | p. 168 |
| Action of H[superscript 1] (X, S[superscript 1]) on [Phi][Characters not reproducible](X)[superscript nabla] | p. 171 |
| Hermitian Maxwell Fields | p. 172 |
| Hermitian Light Bundles | p. 175 |
| Hermitian Light Bundles over Path-Connected Spaces | p. 178 |
| Equivariant Actions of H[superscript 1](X, C[Characters not reproducible]) (Continued) | p. 181 |
| The Kernel of the Map [tau] | p. 186 |
| Hermitian Counterpart (Continued) | p. 191 |
| The Maxwell Group [Phi][Characters not reproducible](X)[superscript nabla] as a Central Extension (Continued) | p. 192 |
| The Hermitian Counterpart (Continued) | p. 194 |
| Cohomological Classification of Maxwell and Hermitian Maxwell Fields | p. 197 |
| Hypercohomology with Respect to a (Differential) A-Complex | p. 197 |
| Sheaf Cohomology | p. 197 |
| Hypercohomology | p. 202 |
| Cech Hypercohomology | p. 206 |
| Cech Hypercohomology Relative to a Two-Term A-Complex | p. 210 |
| Identification of H[superscript 1] (X,[epsilon superscript 0] [Characters not reproducible] [epsilon superscript 1]) | p. 212 |
| Cech Hypercohomology, with Respect to the Two-Term Z-Complex A[Characters not reproducible] [Characters not reproducible] [Omega superscript 1] | p. 216 |
| Characterization of the (Abelian) Cech Hypercohomology Group H[superscript 1] (X, A[Characters not reproducible] [Characters not reproducible] [Omega superscript 1]) | p. 218 |
| Cohomological Wording of the Maxwell Group | p. 221 |
| Abstract Maxwell Equations | p. 227 |
| The Hermitian Analogue | p. 230 |
| Geometric Prequantization | p. 233 |
| Symplectic Sheaves | p. 233 |
| Prequantizable Symplectic Sheaves | p. 237 |
| The Hermitian Framework | p. 242 |
| Cohomological Classification of (Abstract) Geometric Prequantizations of Hermitian Maxwell Fields with a Given Field Strength | p. 246 |
| Prequantization of Elementary Particles | p. 250 |
| Bosonic Case | p. 251 |
| The Chern Isomorphism (Continued), and Consequences | p. 252 |
| Geometric Prequantization of Bosons (Continued) | p. 256 |
| Fermionic Case | p. 257 |
| Pull-Back of Maxwell Fields | p. 259 |
| Geometric Prequantization of Fermions (Continued) | p. 267 |
| References | p. 273 |
| Index of Notation | p. 281 |
| Index | p. 289 |
| Table of Contents provided by Ingram. All Rights Reserved. |