01:15:09

Quantum Theory, Lecture 25: Quantum Computing. Quantum Cryptography. Deutsch's Algorithm.

01:20:10

Quantum Theory, Lecture 24: Dirac Equation. Dirac Sea. Magnetic Moment of the Electron.

01:19:55

Quantum Theory, Lecture 21: Relativistic Quantum Mechanics. The Need for Quantum Field Theory.

01:13:09

Quantum Theory, Lecture 20: Interaction Picture. Dyson Series. Fermi's Golden Rule.

01:19:07

Quantum Theory, Lecture 19: Spinors. Poincare Group. Time-Dependent Perturbation Theory.

01:22:54

Quantum Theory, Lecture 18: Representations of the Lorentz Group. Spinors.

01:20:15

Quantum Theory, Lecture 17: Representations of SU(2). Galilean Boost Invariance.

01:22:55

Quantum Theory, Lecture 16: Angular Momentum. Spin. Representations of SU(2).

01:20:28

Quantum Theory, Lecture 15: Continuous Symmetries. Lie Groups & Algebras. Angular Momentum.

01:20:01

Quantum Theory, Lecture 14: Time Reversal. Anti-Unitary Operators. Lattice Symmetry. Band Structure.

01:20:45

Quantum Theory, Lecture 13: Symmetries. Groups & Representations. Parity. Identical Particles.

01:21:29

Quantum Theory, Lecture 12: Bose-Einstein Condensate. Euclidean Time Formalism.

01:19:34

Quantum Theory, Lecture 11: Von Neumann Entropy. Canonical Ensemble. Bose-Einstein & Fermi-Dirac.

01:24:14

Quantum Theory, Lecture 10: Entanglement. Tensor Products. Measurement.

01:18:45

Quantum Theory, Lecture 9: Quantum Statistical Mechanics. Density Matrices. Ensembles.

01:21:27

Quantum Theory, Lecture 8: WKB Approximation. Bohr-Sommerfeld Quantization. Euclidean Time.

01:22:56

Quantum Theory, Lecture 7: Harmonic Oscillator. Raising and Lowering Operators. Coherent States.

01:22:30

Quantum Theory, Lecture 6: Path Integrals. Propagators. Aharonov-Bohm Effect.

01:21:13

Quantum Theory, Lecture 5: Schrodinger Equation. Hamilton-Jacobi Equation. Path Integrals.

01:22:16

Quantum Theory, Lecture 4.5: Time Evolution Operator. Dyson Series. Time-Ordered Exponential.

01:22:10

Quantum Theory, Lecture 4: Wave Functions, Uncertainty Relation.

01:15:15

Quantum Theory, Lecture 3: Unitary Operators and Symmetries. The Problem of Quantization.

01:18:57

Quantum Theory, Lecture 2: Linear Algebra. Operators and Observables.

01:21:42

Quantum Theory, Lecture 1: Introduction. Quantum Kinematics. Hilbert Spaces. Bras and Kets.

29:33

Classical Mechanics, Lecture 24: Review.

01:04:30

Classical Mechanics, Lecture 23: Chaos. Logistic Equation. Adiabatic Invariants.

01:21:29

Classical Mechanics, Lecture 22: Chaos. Attractors. Lyapunov Exponents.

01:20:41

Classical Mechanics, Lecture 21: Quantization. Integrable Systems. KAM Theorem.

01:26:07

Classical Mechanics, Lecture 20: Poincare Recurrence Theorem. Hamilton-Jacobi Equation.

01:20:27

Classical Mechanics, Lecture 19: Hamiltonian Evolution on Phase Space. Liouville's Theorem.

01:15:09

Classical Mechanics, Lecture 18: Canonical Transformations. Generating Functions.

01:20:22

Classical Mechanics, Lecture 17: Hamiltonian Evolution. Poisson Brackets. Noether's Theorem.

01:15:47

Classical Mechanics, Lecture 16: Hamiltonian Mechanics. Phase Space.

01:18:46

Classical Mechanics, Lecture 15: Systems with Many Degrees of Freedom. Normal Modes.

01:15:39

Classical Mechanics, Lecture 14: Euler Angles. Systems with Many Degrees of Freedom.

01:21:13

Classical Mechanics, Lecture 13: Motion of Rigid Bodies.

01:21:40

Classical Mechanics, Lecture 12: Motion of Rigid Bodies. Inertia Tensor.

01:22:11

Classical Mechanics, Lecture 11: Rotating Coordinate Systems. Foucault's Pendulum.

01:17:51

Classical Mechanics, Lecture 10: Rotating Reference Frames. Centrifugal, Coriolis and Euler Forces.

01:18:22

Classical Mechanics, Lecture 9: Kepler's Laws. Planetary Orbits. Non-inertial Reference Frames.

01:15:53

Classical Mechanics, Lecture 8: Solution of the Two Body Problem.

48:58

Classical Mechanics, Lecture 7: Noether's Theorem. Two Body Problem.

01:21:02

Classical Mechanics, Lecture 6: Driven Oscillators. General One Dimensional Systems.

01:19:28

Classical Mechanics, Lecture 5: Harmonic Oscillator. Damped & Driven Oscillators. Greens Functions.

01:19:30

Classical Mechanics, Lecture 4: Lagrange Multipliers. Near Equilibrium Dynamics. Oscillators.

01:25:07

Classical Mechanics, Lecture 3: Action Principle. Calculus of Variations.

52:19

Classical Mechanics, Lecture 2: Lagrangian Mechanics. Euler-Lagrange Equation. Hamiltonians.

01:24:37

Classical Mechanics, Lecture 1: Introduction. Degrees of Freedom. Lagrangian Dynamics.

25:37

Modern Physics, Lecture 38: Postulates of Quantum Mechanics. Measurements. Schrodinger's Cat.

55:14

Modern Physics, Lecture 37: Quantum Mechanics. Particle in a Box. Born Rule.

48:51

Modern Physics, Lecture 36: Quantum Mechanics. Observables. Heisenberg Uncertainty.

49:59

Modern Physics, Lecture 35: Quantum Mechanics. Observables. Expectation Values.

48:55

Modern Physics, Lecture 34: Quantum Mechanics. Schrodinger Equation. Plane Waves.

52:34

Modern Physics, Lecture 32: Quantum Mechanics. The Wave Function.

41:47

Modern Physics, Lecture 31: Quantization. Wave Phenomena. The Bohr Model.

52:25

Modern Physics, Lecture 30: Wave/Particle Duality. Compton Scattering. Interference.

40:34

Modern Physics, Lecture 29: Wave/Particle Duality. Double Slit Experiment.

53:58

Modern Physics, Lecture 28: Big Bang Cosmology. Cosmological Structure.

46:49

Modern Physics, Lecture 23: Tests of General Relativity. Gravitational Lensing.

52:48

Modern Physics, Lecture 4: Special Relativity. Postulates of Relativity.