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1.1 Review of Maxwell's Equations
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Fundamentals of Nano and Quantum Photonics
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- 1 1.1 Review of Maxwell's Equations
- 2 1.2 Wave Equation
- 3 1.3 Dispersion Relation
- 4 1.4 Propagating and Evanescent Waves
- 5 1.5 Diffraction Limit and Spatial Frequencies
- 6 1.6 Plane Waves
- 7 2.1 Optical Response of Materials
- 8 2.2 Lorentz Model
- 9 2.3 Properties of Lorentz Oscillator Model
- 10 2.4 Drude-Lorentz Model for Metals
- 11 2.5 Kramers-Kronig Relation
- 12 2.6 Engineering Optical Response of Materials
- 13 3.1 Low dimensional systems
- 14 3.2 Absorption in Semiconductors
- 15 3.3 Optical gain in semiconductors
- 16 3.4 Absorption in low-dimensional semiconductors
- 17 3.5 Selection rules for optical processes
- 18 4.1 Scattering of EM radiation
- 19 4.2 LSPR: Quasi-static approximation
- 20 4.3 Size dependence of Plasmon Resonance
- 21 4.4 Tuning Plasmonic Resonances
- 22 4.5 Surface Plasmon Polariton(SPP)
- 23 4.6 Understanding SPP Dispersion Diagram
- 24 4.7 Exciting Surface Plasmon Polaritons
- 25 4.8 Analytical Calculation of Scattering Coefficients - IPython code overview
- 26 5.1 EM Waves in Multilayer Stack - T Matrix formulation
- 27 5.2 Photonic Bandgap in 1D
- 28 5.3 EM Waves in 1D Photonic Crystal
- 29 5.4 Diffracton Grating
- 30 5.5 Applications of Photonic Crystals
- 31 5.6 PhC in 1D - T-matrix examples
- 32 6.1 Introduction to Metamaterials
- 33 6.2 Metamaterials at GHz and THz frequecies
- 34 6.3 Negative index materials at optical frequencies
- 35 6.4 Plasmonic Metasurfaces
- 36 6.5 Dielectric Metasurfaces
- 37 7.1 Tunable and Active Metamaterials
- 38 7.2 Radiative Absorption and Emission
- 39 7.3 Miniaturization of Integrated Photonic Devices
- 40 7.4 Recent trends in nanoscale lasers
- 41 7.5 Non-Hermitian Systems
- 42 8.1 Resonant light-atom interactions
- 43 8.2 Experimental observation of Rabi oscillations
- 44 8.3 Atom-Cavity Interaction - Weak and strong coupling regimes
- 45 8.4 Experimental observation of weak and strong coupling
- 46 8.5 Fabrication of nanophotonic structures - 1
- 47 8.6 Fabrication of nanophotonic structures - 2
- 48 9.1 Measuring light quanta
- 49 9.2 Photon Statistics
- 50 9.3 Photodetection and shot noise limit
- 51 9.4 Second order correlation function
- 52 10.1 Hanbury Brown-Twiss Experiment with Photons
- 53 10.2 EM Waves as harmonic oscillator
- 54 10.3 Vacuum fluctuations
- 55 10.4 Coherent and squeezed states
- 56 11.1 Squeezed and photon number states
- 57 11.2 Application of squeezed states
- 58 11.3 Preliminaries for quantum theory of light
- 59 11.4 Quantum theory of light
- 60 11.5 Operator solution of quantum harmonic oscillator
- 61 12.1 Photon number states
- 62 12.2 Field quadratures and operators
- 63 12.3 Uncertainty relations for quantum light
- 64 12.4 Applications of quantum light - Quantum Key Distribution
- 65 Fundamentals of Nano and Quantum Photonics - 2024
- 66 Fundamentals of Nano and Quantum Photonics
- 67 LIVE_Fundamentals of Nano and Quantum Photonics - Prof. Naresh Kumar Emani
