General Relativity (Petters)

Math 236/Phys 292, GENERAL RELATIVITY (Petters)

Introduction to the basic concepts and techniques of General Relativity. This is a core course for students interested in cosmology, string theory, gravitational lensing, theoretical astrophysics, or related subjects.

Prerequisites: a basic facility with multivariable calculus and linear algebra.

Texts:

R. M. Wald, General Relativity (University of Chicago Press, Chicago, 1984).
A. O. Petters, H. Levine, and J. Wambsganss, Singularity Theory and Gravitational Lensing (Birkhauser, Boston, 2001).

Supplemental References:

E. Bertschinger, Notes on General Relativity
S. Carroll, Notes on General Relativity
S. Chandrasekhar, The Mathematical Theory of Black Holes (Clarendon Press, Oxford, 1992).
J. Hartle, Gravity: An Introduction to Einstein's General Relativity (Addison Wesley, San Francisco, 2003).
C. Misner, K. Thorne, and J. A. Wheeler, Gravitation (W. H. Freeman and Company, San Francisco, 1973).
B. Schutz, A First Course in General Relativity (Cambridge University Press, Cambridge, 1985).
S. Weinberg, Gravitation and Cosmology (John Wiley and Sons, New York, 1972).

COURSE OUTLINE (tentative):

1. Introduction

Newtonian gravity
Special relativity
General relativity

2. Manifolds and Tensor Fields

Topological spaces and manifolds
Tangent vectors, tangent maps, and curves
Vector fields and One-Forms
Tensors: multilinearity, fields, and coordinate transformations
Tensor contractions

3. Spacetimes

Metric tensors and isometries
Causality and time orientation
Mathematical model of spacetime
Examples of spacetimes

4. Spacetime Geometry

Minkowski geometry
Levi-Civita covariant derivative
Parallel transport, geodesics, and Killing vector fields
Exponential map and normal coordinates
Type changing, metric contraction, and divergence
Riemann, Ricci, and scalar curvatures

5. Spacetime Matter Content

Particles and energy-momentum
Fluids: particle density and particle flux
Dust flows and perfect fluids
Stress-energy tensor
Local conservation of stress-energy

6. The Einstein Equation

The Principle of Equivalence
Summary of general relativity's core assumptions
Einstein's equation and the cosmological constant
Analogies between general relativity, classical mechanics, and electromagnetism
The Newtonian limit

7. Application I: Big Bang Cosmology

Modeling the cosmos under spatial homogeneity and isotropy
Einstein's equations for a Robertson-Walker spacetime
Equations of state: matter, radiation, and the vacuum
Dynamical equations and cosmological parameters
Dynamics of a Robertson-Walker universe

8. Application II: Gravitational Lensing

Spacetime geometry of a gravitational lens system
Gravitational lenses as density perturbations
Fermat's principle and time delay functions
Lensed images, magnification, and flux conservation
Critical curves and caustics
Lensing observables
Applications: dark matter, Hubble's constant, extra-solar planets, etc.

9. Application III: Schwarzschild Black Hole

Schwarzschild metric
Gravitational redshift
Energy diagrams and classification of geodesic orbits
Perihelion precession and Mercury
Relativistic gravitational lensing
The Galactic Black Hole (guest lecturer)

10. Application IV: Gravitational Waves

Linearized Einstein equations
Plane gravitational waves
Gravitational wave action on freely falling particles
Gravitational wave polarizations
Detection of gravitational waves: LIGO (guest lecturer)

Grade: based on problem sets.