Lecture 1 - Main differences between classical and quantum mechanics
Lecture 2 - Introduction to Coherence and Stochastic Processes
Lecture 3 - The Joint Probability Function used in Classical Optics: The Correlation Functions
Lecture 4 - Second-order Coherence Theory (Temporal)
Lecture 5 - Quantifying the Temporal Correlations
Lecture 6 - Second-order Coherence Theory (Spatial); Spatial Correlations
Lecture 7 - Quantifying the Spatial Correlations
Lecture 8 - Second-order Coherence Theory (Angular); Angular Correlations
Lecture 9 - Second-order Coherence Theory (Polarization)
Lecture 10 - Degree of Polarization
Lecture 11 - Coherent Mode Representation of Optical Fields
Lecture 12 - Review of Quantum Mechanics
Lecture 13 - Quantum Mechanical Correlation Functions
Lecture 14 - Basics of Nonlinear Optics
Lecture 15 - Two-Photon State Produced by Parametric Down-Conversion
Lecture 16 - Coherence and Quantum Entanglement
Lecture 17 - Temporal Two-Photon Interference
Lecture 18 - Some example of Two-Photon Interference Effects
Lecture 19 - Spatial Two-Photon Interference
Lecture 20 - Quantum Measurements
Lecture 21 - Can the Quantum Mechanical Description of Physical Reality be Considered Complete ?
Lecture 22 - Hidden Variable Interpretation of Quantum Mechanics
Lecture 23 - Bell Inequalities
Lecture 24 - Entanglement Verification
Lecture 25 - Entanglement Quantification and Connection Between Coherence and Entanglement
Lecture 26 - 84 Quantum Cryptography
Lecture 27 - Quantum Teleportation
