Class: Tuesdays and Thursdays, 9:30-10:45, Room 102 (Meyer Building)
Instructor: Roman Scoccimarro
Office Hours: Mondays 2-3PM, Room 506 Meyer. Or just email me.
Grades: Homework (60%), Final Exam (40%)
Recitations: Paul Duffell (pcd233 AT [Wednesdays at 5pm in Room 333 Meyer]

Final Exam

Will be on May 11, 8AM-9:50AM


  • J.B. Hartle, Gravity, 2003, Addison Wesley

    See also,

  • B. Schutz, A First Course in General Relativity, 2nd edition, 2009, Cambridge Univeristy Press

    Homework [Due on Fridays, 3PM, Meyer 538]

  • HMW1 [Feb 5]: Problems 2.4,3.2,4.2,4.7,4.13,4.18,5.2,5.4,5.9
  • HMW2 [Feb 12]: Problems 6.3,6.8,6.11
  • HMW3 [Feb 19]: Problems 6.13,6.14,7.5,7.10,7.14
  • HMW4 [Feb 26]: Problems 7.22,7.23,8.3,8.5,8.9,8.11
  • HMW5 [Mar 5]: Problems 9.1,9.2,9.5,9.6
  • HMW6 [Mar 12]: Problems 9.9,9.10,9.18,9.21
  • HMW7 [Mar 26]: Problems 10.4,12.3,12.4,12.5
  • HMW8 [Apr 2]: Problems 12.8,12.11,12.13,12.14
  • HMW9 [Apr 9]: Problems 16.4,16.6,16.7,16.8,17.6,18.3
  • HMW10 [Apr 16]: Problems 18.4,18.5,18.12,18.16,18.19,18.28
  • HMW11 [Apr 23]: Problems 20.4,20.7,20.16,20.17,21.1,21.6,21.7
  • HMW12 [Apr 30]: Problems 21.13,21.14,22.8,22.9,22.13

    Lecture Notes

    L1, L2, L3, L4, L5, L6, L7, L8, L9, L10, L11, L12, L13, L14, L15, L16, L17, L18

    Lecture Schedule (L# refers to notes above)

    L1[Jan19-21] L2[Jan26] L3[Jan28-Feb2] L4[Feb2-4] L5[Feb9] L6[Feb11-16] L7[Feb16-18] L8[Feb23-25] L9[Feb25-Mar2] L10[Mar2-4] L11[Mar9-11] L12[Mar23-25] L13[Mar30-Apr1] L14[Apr6-8] L15[Apr13-15] L16[Apr15-20] L17[Apr22] L18[Apr27-29]

    Gravitational Lensing Examples: Abell1689, Abell2218

    Course Outline

  • Special Relativity (2 weeks)
    - Inertial Frames, Principle of Relativity, Lorentz Transformations, Michelson Morley Experiment
    - Spacetime, Coordinates and Invariance
    - Relativistic Kinematics and Dynamics
    - Variational Principle for Free Particle Motion, Light Rays

  • Gravity as Geometry (2 weeks)
    - Equivalence principle, Tests of Equality of Inertial and Gravitational Mass
    - Clocks in a Gravitational Field, Applications to the GPS
    - Local Inertial Frames, Light Cones, World Lines, Vectors
    - Geodesics, Symmetries and Conservation Laws

  • Black Holes (3 weeks)
    - Schwarszschild Geometry, Gravitational Redshift
    - Particle Orbits: Precession of the Perihelion of Mercury
    - Light Ray Orbits: Deflection and time Delay of Light (Gravitational Lensing)
    - Solar System Tests of General Relativity
    - Gravitational Collapse to a Black Hole
    - Astrophysical Back Holes (X-ray binaries, Galaxies, Hawking Radiation)

  • Gravitational Waves (1 week)
    - Linearized Gravitational Waves, Energy, Polarization
    - Detecting Gravitational Waves, Inteferometers

  • Cosmology (2 weeks)
    - Homogeneous and Isotropic Spacetimes: Expansion of the Universe, Cosmological Redshift
    - Matter, Radiation, Vacuum Energies: Evolution of FRW Models

  • Einstein Equations (3 weeks)
    - Tensors, Covariant Derivatives
    - Tidal Gravitational Forces, Riemann Curvature
    - Energy Momentum Conservation
    - Einstein Field Equations, Newtonian Limit
    - Applications: Production of Weak Gravitational Waves, Quadrupole Formula, Gravitational Radiation from Binary Pulsars