| Overview |
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| 1 |
Overview of Course, Related Subjects; History of Physics to 1900 |
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| Background and History |
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| 2 |
Galilean Transformation, Inertial Reference Frames |
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| 3 |
Classical Wave Equations; Transformation to Other Frames
Michelson-morley Experiment; Ether |
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| 4 |
Postulates of Special Relativity |
PS 1 Due |
| 5 |
First Discussion of Minkowski Diagrams, World Lines |
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| Relativistic Kinematics |
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| 5 (cont.) |
Derivation of Lorentz-Einstein Transformations
Matrix Representation
Introduction of Four-vectors |
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| 6 |
Time Dilation and Length Contraction
Decay of Atmospheric Muons, Pole Vaulter Problem |
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| 7 |
Alternative Looks at Time Dilation and Length Contraction |
PS 2 Due |
| 7-8 |
Spacetime Intervals |
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| 8 |
First Discussion of Accelerated Clocks
Addition of Velocities
Angle Transformation for Trajectories |
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| 9 |
Doppler Effect
Classical Doppler Effect for Sound
Relativistic Doppler Effect
Astrophysical Examples; Relativistic and Superluminal Jets Stellar Aberration |
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| 10 |
Alternate Approach to Doppler Effect and Angle Transformation via Transformation of Phase of Plane Waves |
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| 11 |
Short Discourse on the Calculus of Variations
Extremization of Path Integrals
Eulers Equations and Constants of the Motion
Brachistochrone Problem |
PS 3 Due |
| 12 |
Extremal Aging for Inertially Moving Clocks
Optional Problems in the Use of the Calculus of Variations - As Applied to Lagragian Mechanics and Other Problems in the Extremization of Path Integrals. Fully Calibrated Minkowski Diagrams
Pole-vaulter Problem |
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| 13 |
Twin Paradox with Constant Velocity Plus a Reversal
Twin Paradox with Arbitrary Acceleration |
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| Relativistic Dynamics |
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| 14 |
Relativistic Momentum
Inferred from Gedanken Experiment with Inelastic Collisions
Relativistic Relations between Force and Acceleration |
PS 4 Due |
| 15 |
Relativistic Version of Work-energy Theorem
Kinetic Energy, Rest Energy, Equivalence of Mass-Energy
E2 - p2 Invariant
Nuclear Binding Energies
Atomic Mass Excesses, Semi-Empirical Binding Energy Equation
Nuclear Reactions
Solar p-p Chain |
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| 16 |
Relativistic Motion in a B Field, Lorentz Force |
Quiz 1 |
| 17 |
Cyclotrons, Synchrotrons
Further Gedanken Experiments Relating to Mass-energy Equivalence, Relativistic Momentum |
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| 18 |
Quantum Nature of Light
Photoelectric Effect, Photons
ß Decay and the Inference of Neutrinos
Absorption and Emission of Light Quanta - Atomic and Nuclear Recoil |
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| 19 |
Mossbauer Effect
Pound-Rebka Experiment |
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| 20 |
Collisions
Between Photons and Moving Atoms
Elastic
Compton
Inverse Compton
Between Photon and Relativistic Particle
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PS 5 Due |
| 21 |
Particle Production
Threshold Energy
Colliding Particle Beams |
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| 22 |
Two Photons Producing an Electron/Positron Pair
Formal Transformation of E and p as a Four-vector
Revisit the Relativistic Doppler Effect |
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| 23 |
Relativistic Invariant E2 - p2 for a Collection of Particles
Transformation of Forces and Accelerations
Example of Minkowski Metric for a "Skewed, but Flat" Space |
PS 6 Due |
| Relativity and Electromagnetism |
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| 24 |
Coulomb's Law
Transformation of Coulomb's Law |
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| 25 |
Force on a Moving Test Charge
Magnetic Field and Relativity
Derivation of Lorentz Force |
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| Red Shifts and Hubble Expansion of the Universe |
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| 26 |
Distance Ladder in Astronomy |
PS 7 Due |
| 27 |
Cosmological Redshifts and the Hubble Law
Newtonian Cosmology
Dynamical Equations for the Scale Factor, a - Including Ordinary Matter, Dark Matter, and Dark Energy |
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| 28 |
Critical Closure Density; Open, Closed, Flat Universe
Solutions for Various Combinations of Ωm and Ωλ
Age of the Universe |
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| 29 |
Relation Between Scale Factor and z from the Doppler Shift
Lookback Age as a Function of z for Given Values of Ωm and Ωλ
Acceleration Parameter as a Function of Scale Factor |
PS 8 Due |
| Equivalence Principle |
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| 30 |
Strong and Weak Principles of Equivalence
Local Equivalence of Gravity and Acceleration
Elevator "Thought Experiments"; Gravitational Red Shift, Light Bending
Relative Acceleration of Test Particles in Falling Elevator of Finite Size |
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| Curved Space Time |
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| 31 |
10-page Handout defining: Einstein Field Equations, Einstein Tensor, Stress-Energy Tensor, Curvature Scalar, Ricci Tensor, Christoffel Symbols, Riemann Curvature Tensor
Definition of the Metric Tensor
Analogy between the Metric Tensor and the Ordinary Potential, and between Einsteins Field Equations and Poissons Equation
Symmetry Arguments by which 6 Schwarzschild Metric Tensor Components Vanish
Symmetry Arguments for why the Non-zero Components are Functions of Radius only |
Quiz 2 |
| 32 |
The Differential Equations for G00 and G11
Shell Radius vs. Bookkeepers Radial Coordinate
Gravitational Red Shift |
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| 33 |
Application to the GPS System
Particle Orbits
Use Euler Equations (for Extremal Aging) in connection with the Schwarzschild Metric to find Constants of the Motion E and L
Derive the Full Expression for the Effective Potential |
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| 34 |
Derive Analytic Results for Radial Motion
Compare Speeds and Energies for Bookkeeper and Shell Observers
Equations of Motion for a General Orbit
Explain how these can be numerically integrated
Expand the Effective Potential in the Weak-field Limit
Kepler's Third Law in the Schwarzschild Metric |
PS 9 Due |
| 35 |
Relativistic Precession in the Weak-field Limit
Taylor-Hulse Binary Neutron Star System
Derivation of the Last Stable Circular Orbit at 6M
Analytic E and L for Circular Orbits
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| 36 |
Photon Trajectories
Derive Differential Equation for the Trajectories
Critical Impact Parameter
Derive Expression for Light Bending in the Weak-field Limit
Shapiro Time Delay
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Optional Quiz 3
PS 10 Due |