General Relativity: An Introduction for Physicists,9780521829519

General Relativity: An Introduction for Physicists

by
ISBN13: 9780521829519
ISBN10: 0521829518
Format: Hardcover
Pub. Date: 2006-03-27
Publisher(s): Cambridge University Press
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Summary

General Relativity: An Introduction for Physicists provides a clear mathematical introduction to Einstein's theory of general relativity. It presents a wide range of applications of the theory, concentrating on its physical consequences. After reviewing the basic concepts, the authors present a clear and intuitive discussion of the mathematical background, including the necessary tools of tensor calculus and differential geometry. These tools are then used to develop the topic of special relativity and to discuss electromagnetism in Minkowski spacetime. Gravitation as spacetime curvature is then introduced and the field equations of general relativity derived. After applying the theory to a wide range of physical situations, the book concludes with a brief discussion of classical field theory and the derivation of general relativity from a variational principle. Written for advanced undergraduate and graduate students, this approachable textbook contains over 300 exercises to illuminate and extend the discussion in the text.

Table of Contents

Preface xv
1 The spacetime of special relativity
1(25)
1.1 Inertial frames and the principle of relativity
1(2)
1.2 Newtonian geometry of space and time
3(1)
1.3 The spacetime geometry of special relativity
3(2)
1.4 Lorentz transformations as four-dimensional 'rotations'
5(1)
1.5 The interval and the lightcone
6(2)
1.6 Spacetime diagrams
8(2)
1.7 Length contraction and time dilation
10(1)
1.8 Invariant hyperbolae
11(1)
1.9 The Minkowski spacetime line element
12(2)
1.10 Particle worldlines and proper time
14(2)
1.11 The Doppler effect
16(2)
1.12 Addition of velocities in special relativity
18(1)
1.13 Acceleration in special relativity
19(2)
1.14 Event horizons in special relativity
21(1)
Appendix 1A: Einstein's route to special relativity
22(2)
Exercises
24(2)
2 Manifolds and coordinates
26(27)
2.1 The concept of a manifold
26(1)
2.2 Coordinates
27(1)
2.3 Curves and surfaces
27(1)
2.4 Coordinate transformations
28(2)
2.5 Summation convention
30(1)
2.6 Geometry of manifolds
31(1)
2.7 Riemannian geometry
32(1)
2.8 Intrinsic and extrinsic geometry
33(3)
2.9 Examples of non-Euclidean geometry
36(2)
2.10 Lengths, areas and volumes
38(4)
2.11 Local Cartesian coordinates
42(2)
2.12 Tangent spaces to manifolds
44(1)
2.13 Pseudo-Riemannian manifolds
45(2)
2.14 Integration over general submanifolds
47(2)
2.15 Topology of manifolds
49(1)
Exercises
50(3)
3 Vector calculus on manifolds
53(39)
3.1 Scalar fields on manifolds
53(1)
3.2 Vector fields on manifolds
54(1)
3.3 Tangent vector to a curve
55(1)
3.4 Basis vectors
56(3)
3.5 Raising and lowering vector indices
59(1)
3.6 Basis vectors and coordinate transformations
60(1)
3.7 Coordinate-independent properties of vectors
61(1)
3.8 Derivatives of basis vectors and the affine connection
62(2)
3.9 Transformation properties of the affine connection
64(1)
3.10 Relationship of the connection and the metric
65(2)
3.11 Local geodesic and Cartesian coordinates
67(1)
3.12 Covariant derivative of a vector
68(2)
3.13 Vector operators in component form
70(1)
3.14 Intrinsic derivative of a vector along a curve
71(2)
3.15 Parallel transport
73(2)
3.16 Null curves, non-null curves and affine parameters
75(1)
3.17 Geodesics
76(1)
3.18 Stationary property of non-null geodesics
77(1)
3.19 Lagrangian procedure for geodesics
78(3)
3.20 Alternative form of the geodesic equations
81(1)
Appendix 3A: Vectors as directional derivatives
81(1)
Appendix 3B: Polar coordinates in a plane
82(5)
Appendix 3C: Calculus of variations
87(1)
Exercises
88(4)
4 Tensor calculus on manifolds
92(19)
4.1 Tensor fields on manifolds
92(1)
4.2 Components of tensors
93(1)
4.3 Symmetries of tensors
94(2)
4.4 The metric tensor
96(1)
4.5 Raising and lowering tensor indices
97(1)
4.6 Mapping tensors into tensors
97(1)
4.7 Elementary operations with tensors
98(2)
4.8 Tensors as geometrical objects
100(1)
4.9 Tensors and coordinate transformations
101(1)
4.10 Tensor equations
102(1)
4.11 The quotient theorem
103(1)
4.12 Covariant derivative of a tensor
104(3)
4.13 Intrinsic derivative of a tensor along a curve
107(1)
Exercises
108(3)
5 Special relativity revisited
111(24)
5.1 Minkowski spacetime in Cartesian coordinates
111(1)
5.2 Lorentz transformations
112(1)
5.3 Cartesian basis vectors
113(2)
5.4 Four-vectors and the lightcone
115(1)
5.5 Four-vectors and Lorentz transformations
116(1)
5.6 Four-velocity
116(2)
5.7 Four-momentum of a massive particle
118(1)
5.8 Four-momentum of a photon
119(1)
5.9 The Doppler effect and relativistic aberration
120(2)
5.10 Relativistic mechanics
122(1)
5.11 Free particles
123(1)
5.12 Relativistic collisions and Compton scattering
123(2)
5.13 Accelerating observers
125(3)
5.14 Minkowski spacetime in arbitrary coordinates
128(3)
Exercises
131(4)
6 Electromagnetism
135(12)
6.1 The electromagnetic force on a moving charge
135(1)
6.2 The 4-current density
136(2)
6.3 The electromagnetic field equations
138(1)
6.4 Electromagnetism in the Lorenz gauge
139(2)
6.5 Electric and magnetic fields in inertial frames
141(1)
6.6 Electromagnetism in arbitrary coordinates
142(2)
6.7 Equation of motion for a charged particle
144(1)
Exercises
145(2)
7 The equivalence principle and spacetime curvature
147(29)
7.1 Newtonian gravity
147(1)
7.2 The equivalence principle
148(1)
7.3 Gravity as spacetime curvature
149(2)
7.4 Local inertial coordinates
151(1)
7.5 Observers in a curved spacetime
152(1)
7.6 Weak gravitational fields and the Newtonian limit
153(2)
7.7 Electromagnetism in a curved spacetime
155(2)
7.8 Intrinsic curvature of a manifold
157(1)
7.9 The curvature tensor
158(1)
7.10 Properties of the curvature tensor
159(2)
7.11 The Ricci tensor and curvature scalar
161(2)
7.12 Curvature and parallel transport
163(2)
7.13 Curvature and geodesic deviation
165(2)
7.14 Tidal forces in a curved spacetime
167(3)
Appendix 7A: The surface of a sphere
170(2)
Exercises
172(4)
8 The gravitational field equations
176(20)
8.1 The energy-momentum tensor
176(2)
8.2 The energy-momentum tensor of a perfect fluid
178(1)
8.3 Conservation of energy and momentum for a perfect fluid
179(2)
8.4 The Einstein equations
181(2)
8.5 The Einstein equations in empty space
183(1)
8.6 The weak-field limit of the Einstein equations
184(1)
8.7 The cosmological-constant term
185(3)
8.8 Geodesic motion from the Einstein equations
188(2)
8.9 Concluding remarks
190(1)
Appendix 8A: Alternative relativistic theories of gravity
191(2)
Appendix 8B: Sign conventions
193(1)
Exercises
193(3)
9 The Schwarzschild geometry
196(34)
9.1 The general static isotropic metric
196(2)
9.2 Solution of the empty-space field equations
198(4)
9.3 Birkhoff' s theorem
202(1)
9.4 Gravitational redshift for a fixed emitter and receiver
202(3)
9.5 Geodesics in the Schwarzschild geometry
205(2)
9.6 Trajectories of massive particles
207(2)
9.7 Radial motion of massive particles
209(3)
9.8 Circular motion of massive particles
212(1)
9.9 Stability of massive particle orbits
213(4)
9.10 Trajectories of photons
217(1)
9.11 Radial motion of photons
218(1)
9.12 Circular motion of photons
219(1)
9.13 Stability of photon orbits
220(1)
Appendix 9A: General approach to gravitational redshifts
221(3)
Exercises
224(6)
10 Experimental tests of general relativity 230(18)
10.1 Precession of planetary orbits
230(3)
10.2 The bending of light
233(3)
10.3 Radar echoes
236(4)
10.4 Accretion discs around compact objects
240(4)
10.5 The geodesic precession of gyroscopes
244(2)
Exercises
246(2)
11 Schwarzschild black holes 248(40)
11.1 The characterisation of coordinates
248(1)
11.2 Singularities in the Schwarzschild metric
249(2)
11.3 Radial photon worldlines in Schwarzschild coordinates
251(1)
11.4 Radial particle worldlines in Schwarzschild coordinates
252(2)
11.5 Eddington–Finkelstein coordinates
254(5)
11.6 Gravitational collapse and black-hole formation
259(1)
11.7 Spherically symmetric collapse of dust
260(4)
11.8 Tidal forces near a black hole
264(2)
11.9 Kruskal coordinates
266(5)
11.10 Wormholes and the Einstein–Rosen bridge
271(3)
11.11 The Hawking effect
274(3)
Appendix 11A: Compact binary systems
277(2)
Appendix 11B: Supermassive black holes
279(3)
Appendix 11C: Conformal flatness of two-dimensional Riemannian manifolds
282(1)
Exercises
283(5)
12 Further spherically symmetric geometries 288(22)
12.1 The form of the metric for a stellar interior
288(4)
12.2 The relativistic equations of stellar structure
292(2)
12.3 The Schwarzschild constant-density interior solution
294(2)
12.4 Buchdahl's theorem
296(1)
12.5 The metric outside a spherically symmetric charged mass
296(4)
12.6 The Reissner–Nordstrom geometry: charged black holes
300(2)
12.7 Radial photon trajectories in the RN geometry
302(2)
12.8 Radial massive particle trajectories in the RN geometry
304(1)
Exercises
305(5)
13 The Kerr geometry 310(45)
13.1 The general stationary axisymmetric metric
310(2)
13.2 The dragging of inertial frames
312(2)
13.3 Stationary limit surfaces
314(1)
13.4 Event horizons
315(2)
13.5 The Kerr metric
317(2)
13.6 Limits of the Kerr metric
319(2)
13.7 The Kerr-Schild form of the metric
321(1)
13.8 The structure of a Kerr black hole
322(5)
13.9 The Penrose process
327(3)
13.10 Geodesics in the equatorial plane
330(2)
13.11 Equatorial trajectories of massive particles
332(1)
13.12 Equatorial motion of massive particles with zero angular momentum
333(2)
13.13 Equatorial circular motion of massive particles
335(2)
13.14 Stability of equatorial massive particle circular orbits
337(1)
13.15 Equatorial trajectories of photons
338(1)
13.16 Equatorial principal photon geodesics
339(2)
13.17 Equatorial circular motion of photons
341(1)
13.18 Stability of equatorial photon orbits
342(2)
13.19 Eddington-Finkelstein coordinates
344(3)
13.20 The slow-rotation limit and gyroscope precession
347(3)
Exercises
350(5)
14 The Friedmann-Robertson-Walker geometry 355(31)
14.1 The cosmological principle
355(1)
14.2 Slicing and threading spacetime
356(1)
14.3 Synchronous coordinates
357(1)
14.4 Homogeneity and isotropy of the universe
358(1)
14.5 The maximally symmetric 3-space
359(3)
14.6 The Friedmann-Robertson-Walker metric
362(1)
14.7 Geometric properties of the FRW metric
362(3)
14.8 Geodesics in the FRW metric
365(2)
14.9 The cosmological redshift
367(1)
14.10 The Hubble and deceleration parameters
368(3)
14.11 Distances in the FRW geometry
371(3)
14.12 Volumes and number densities in the FRW geometry
374(2)
14.13 The cosmological field equations
376(3)
14.14 Equation of motion for the cosmological fluid
379(2)
14.15 Multiple-component cosmological fluid
381(1)
Exercises
381(5)
15 Cosmological models 386(42)
15.1 Components of the cosmological fluid
386(4)
15.2 Cosmological parameters
390(2)
15.3 The cosmological field equations
392(1)
15.4 General dynamical behaviour of the universe
393(4)
15.5 Evolution of the scale factor
397(3)
15.6 Analytical cosmological models
400(8)
15.7 Look-back time and the age of the universe
408(3)
15.8 The distance-redshift relation
411(2)
15.9 The volume-redshift relation
413(2)
15.10 Evolution of the density parameters
415(2)
15.11 Evolution of the spatial curvature
417(1)
15.12 The particle horizon, event horizon and Hubble distance
418(3)
Exercises
421(7)
16 Inflationary cosmology 428(39)
16.1 Definition of inflation
428(2)
16.2 Scalar fields and phase transitions in the very early universe
430(1)
16.3 A scalar field as a cosmological fluid
431(2)
16.4 An inflationary epoch
433(1)
16.5 The slow-roll approximation
434(1)
16.6 Ending inflation
435(1)
16.7 The amount of inflation
435(2)
16.8 Starting inflation
437(1)
16.9 'New' inflation
438(2)
16.10 Chaotic inflation
440(1)
16.11 Stochastic inflation
441(1)
16.12 Perturbations from inflation
442(1)
16.13 Classical evolution of scalar-field perturbations
442(4)
16.14 Gauge invariance and curvature perturbations
446(3)
16.15 Classical evolution of curvature perturbations
449(3)
16.16 Initial conditions and normalisation of curvature perturbations
452(4)
16.17 Power spectrum of curvature perturbations
456(2)
16.18 Power spectrum of matter-density perturbations
458(1)
16.19 Comparison of theory and observation
459(3)
Exercises
462(5)
17 Linearised general relativity 467(31)
17.1 The weak-field metric
467(3)
17.2 The linearised gravitational field equations
470(2)
17.3 Linearised gravity in the Lorenz gauge
472(1)
17.4 General properties of the linearised field equations
473(1)
17.5 Solution of the linearised field equations in vacuo
474(1)
17.6 General solution of the linearised field equations
475(5)
17.7 Multipole expansion of the general solution
480(1)
17.8 The compact-source approximation
481(2)
17.9 Stationary sources
483(2)
17.10 Static sources and the Newtonian limit
485(1)
17.11 The energy–momentum of the gravitational field
486(4)
Appendix 17A: The Einstein–Maxwell formulation of linearised gravity
490(3)
Exercises
493(5)
18 Gravitational waves 498(26)
18.1 Plane gravitational waves and polarisation states
498(3)
18.2 Analogy between gravitational and electromagnetic waves
501(1)
18.3 Transforming to the transverse-traceless gauge
502(2)
18.4 The effect of a gravitational wave on free particles
504(3)
18.5 The generation of gravitational waves
507(4)
18.6 Energy flow in gravitational waves
511(2)
18.7 Energy loss due to gravitational-wave emission
513(3)
18.8 Spin-up of binary systems: the binary pulsar PSR B1913+16
516(1)
18.9 The detection of gravitational waves
517(3)
Exercises
520(4)
19 A variational approach to general relativity 524(31)
19.1 Hamilton's principle in Newtonian mechanics
524(3)
19.2 Classical field theory and the action
527(2)
19.3 Euler–Lagrange equations
529(2)
19.4 Alternative form of the Euler–Lagrange equations
531(2)
19.5 Equivalent actions
533(1)
19.6 Field theory of a real scalar field
534(2)
19.7 Electromagnetism from a variational principle
536(3)
19.8 The Einstein–Hilbert action and general relativity in vacuo
539(3)
19.9 An equivalent action for general relativity in vacuo
542(1)
19.10 The Palatini approach for general relativity in vacuo
543(2)
19.11 General relativity in the presence of matter
545(1)
19.12 The dynamical energy–momentum tensor
546(3)
Exercises
549(6)
Bibliography 555(1)
Index 556

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