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1 From absolute space and time to influenceable spacetime: an overview 3 1.1 Definition of relativity 3 1.2 Newton's laws and inertial frames 4 1.3 The Galilean transformation 5 1.4 Newtonian relativity 6 1.5 Objections to absolute space; Mach's principle 7 1.6 The ether 9 1.7 Michelson and Morley's search for the ether 9 1.8 Lorentz's ether theory 10 1.9 Origins of special relativity 12 1.10 Further arguments for Einstein's two postulates 14 1.11 Cosmology and first doubts about inertial frames 15 1.12 Inertial and gravitational mass 16 1.13 Einstein's equivalence principle 18 1.14 Preview of general relativity 20 1.15 Caveats on the equivalence principle 22 1.16 Gravitational frequency shift and light bending 24 Exercises 1 27 I Special Relativity 31 2 Foundations of special relativity; The Lorentz transformation 33 2.1 On the nature of physical theories 33 2.2 Basic features of special relativity 34 2.3 Relativistic problem solving 36 2.4 Relativity of simultaneity, time dilation and length contraction: a preview 38 2.5 The relativity principle and the homogeneity and isotropy of inertial frames 39 2.6 The coordinate lattice; Definitions of simultaneity 41 2.7 Derivation of the Lorentz transformation 43 2.8 Properties of the Lorentz transformation 47 2.9 Graphical representation of the Lorentz transformation 49 2.10 The relativistic speed limit 54 2.11 Which transformations are allowed by the relativity principle? 57 Exercises 2 58 3 Relativistic kinematics 61 3.1 Introduction 61 3.2 World-picture and world-map 61 3.3 Length contraction 62 3.4 Length contraction paradox 63 3.5 Time dilation; The twin paradox 64 3.6 Velocity transformation; Relative and mutual velocity 68 3.7 Acceleration transformation; Hyperbolic motion 70 3.8 Rigid motion and the uniformly accelerated rod 71 Exercises 3 73 4 Relativistic optics 77 4.1 Introduction 77 4.2 The drag effect 77 4.3 The Doppler effect 78 4.4 Aberration 81 4.5 The visual appearance of moving objects 82 Exercises 4 85 5 Spacetime and four-vectors 89 5.1 The discovery of Minkowski space 89 5.2 Three-dimensional Minkowski diagrams 90 5.3 Light cones and intervals 91 5.4 Three-vectors 94 5.5 Four-vectors 97 5.6 The geometry of four-vectors 101 5.7 Plane waves 103 Exercises 5 105 6 Relativistic particle mechanics 108 6.1 Domain of sufficient validity of Newtonian mechanics 108 6.2 The axioms of the new mechanics 109 6.3 The equivalence of mass and energy 111 6.4 Four-momentum identities 114 6.5 Relativistic billiards 115 6.6 The zero-momentum frame 117 6.7 Threshold energies 118 6.8 Light quanta and de Broglie waves 119 6.9 The Compton effect 121 6.10 Four-force and three-force 123 Exercises 6 126 7 Four-tensors; Electromagnetism in vacuum 130 7.1 Tensors: Preliminary ideas and notations 130 7.2 Tensors: Definition and properties 132 7.3 Maxwell's equations in tensor form 139 7.4 The four-potential 143 7.5 Transformation of e and b; The dual field 146 7.6 The field of a uniformly moving point charge 148 7.7 The field of an infinite straight current 150 7.8 The energy tensor of the electromagnetic field 151 7.9 From the mechanics of the field to the mechanics of material continua 154 Exercises 7 157 II General Relativity 163 8 Curved spaces and the basic ideas of general relativity 165 8.1 Curved surfaces 165 8.2 Curved spaces of higher dimensions 169 8.3 Riemannian spaces 172 8.4 A plan for general relativity 177 Exercises 8 180 9 Static and stationary spacetimes 183 9.1 The coordinate lattice 183 9.2 Synchronization of clocks 184 9.3 First standard form of the metric 186 9.4 Newtonian support for the geodesic law of motion 188 9.5 Symmetries and the geometric characterization of static and stationary spacetimes 191 9.6 Canonical metric and relativistic potentials 195 9.7 The uniformly rotating lattice in Minkowski space 198 Exercises 9 200 10 Geodesics, curvature tensor and vacuum field equations 203 10.1 Tensors for general relativity 203 10.2 Geodesics 204 10.3 Geodesic coordinates 208 10.4 Covariant and absolute differentiation 210 10.5 The Riemann curvature tensor 217 10.6 Einstein's vacuum field equations 221 Exercises 10 224 11 The Schwarzschild metric 228 11.1 Derivation of the metric 228 11.2 Properties of the metric 230 11.3 The geometry of the Schwarzschild lattice 231 11.4 Contributions of the spatial curvature to post-Newtonian effects 233 11.5 Coordinates and measurements 235 11.6 The gravitational frequency shift 236 11.7 Isotropic metric and Shapiro time delay 237 11.8 Particle orbits in Schwarzschild space 238 11.9 The precession of Mercury's orbit 241 11.10 Photon orbits 245 11.11 Deflection of light by a spherical mass 248 11.12 Gravitational lenses 250 11.13 de Sitter precession via rotating coordinates 252 Exercises 11 254 12 Black holes and Kruskal space 258 12.1 Schwarzschild black holes 258 12.2 Potential energy; A general-relativistic 'proof' of E = mc2 263 12.3 The extendibility of Schwarzschild spacetime 265 12.4 The uniformly accelerated lattice 267 12.5 Kruskal space 272 12.6 Black-hole thermodynamics and related topics 279 Exercises 12 281 13 An exact plane gravitational wave 284 13.1 Introduction 284 13.2 The plane-wave metric 284 13.3 When wave meets dust 287 13.4 Inertial coordinates behind the wave 288 13.5 When wave meets light 290 13.6 The Penrose topology 291 13.7 Solving the field equation 293 Exercises 13 295 14 The full field equations; de Sitter space 296 14.1 The laws of physics in curved spacetime 296 14.2 At last, the full field equations 299 14.3 The cosmological constant 303 14.4 Modified Schwarzschild space 304 14.5 de Sitter space 306 14.6 Anti-de Sitter space 312 Exercises 14 314 15 Linearized general relativity 318 15.1 The basic equations 318 15.2 Gravitational waves; The TT gauge 323 15.3 Some physics of plane waves 325 15.4 Generation and detection of gravitational waves 330 15.5 The electromagnetic analogy in linearized GR 335 Exercises 15 341 III Cosmology 345 16 Cosmological spacetimes 347 16.1 The basic facts 347 16.2 Beginning to construct the model 358 16.3 Milne's model 360 16.4 The Friedman-Robertson-Walker metric 363 16.5 Robertson and Walker's theorem 368 Exercises 16 369 17 Light propagation in FRW universes 373 17.1 Representation of FRW universes by subuniverses 373 17.2 The cosmological frequency shift 374 17.3 Cosmological horizons 376 17.4 The apparent horizon 382 17.5 Observables 384 Exercises 17 388 18 Dynamics of FRW universes 391 18.1 Applying the field equations 391 18.2 What the field equations tell us 393 18.3 The Friedman models 397 18.4 Once again, comparison with observation 406 18.5 Inflation 411 18.6 The anthropic principle 415 Exercises 18 416