| 1 | Lecture 1: Conductivity of materials, Drude’s theory and its failures | PDF unavailable |
| 2 | Lecture 2 : Free electron theory | PDF unavailable |
| 3 | Lecture 3: Free electron theory | PDF unavailable |
| 4 | Lecture 4: Crystal structure, Reciprocal lattice I | PDF unavailable |
| 5 | Lecture 5: Reciprocal lattice II, Brillouin zone and Bragg’s diffraction condition | PDF unavailable |
| 6 | Lecture 6: Electrons in a crystal, Bloch’s electron | PDF unavailable |
| 7 | Lecture 7: Free electron band diagrams in an empty lattice | PDF unavailable |
| 8 | Lecture 8: Effect of periodic potential, Origin of band-gap through Kronig-Penny model | PDF unavailable |
| 9 | Lecture 9: Electron dynamics | PDF unavailable |
| 10 | Lecture 10: Conduction in relation to band diagrams | PDF unavailable |
| 11 | Lecture 11: Semiconductor E-k diagrams and their material properties | PDF unavailable |
| 12 | Lecture 12: Equilibrium carrier statistics in semiconductors: density of states, fermi function and population density in bands | PDF unavailable |
| 13 | Lecture 13: Equilibrium carrier statistics in semiconductors: qualitative examination of carrier densities in conduction and valence bands | PDF unavailable |
| 14 | Lecture 14: Equilibrium carrier statistics in semiconductors: quantitative examination of carrier densities in intrinsic semiconductor | PDF unavailable |
| 15 | Lecture 15: Doping in semiconductors | PDF unavailable |
| 16 | Lecture 16: Equilibrium carrier statistics in semiconductors: complete ionization of dopant levels | PDF unavailable |
| 17 | Lecture 17: Equilibrium carrier statistics in semiconductors: carrier freeze out | PDF unavailable |
| 18 | Lecture 18: Semiconductor junctions in band-diagrams | PDF unavailable |
| 19 | Lecture 19: Linear dielectric behavior | PDF unavailable |
| 20 | Lecture 20: Non-linear dielectric behavior | PDF unavailable |
| 21 | Lecture 21: Carrier recombination-generation-I: band-to-band transition | PDF unavailable |
| 22 | Lecture 22: Carrier recombination-generation –II: Other mechanisms | PDF unavailable |
| 23 | Lecture 23: R-G statistics via R-G centers | PDF unavailable |
| 24 | Lecture 24: Optoelectronic materials and bandgap engineering | PDF unavailable |
| 25 | Lecture 25: Optical properties of materials | PDF unavailable |
| 26 | Lecture 26: Optical properties of single interfaces: Fresnal reflection coefficients | PDF unavailable |
| 27 | Lecture 27: Optical Properties of two interfaces: thin film case | PDF unavailable |
| 28 | Lecture 28: Drift | PDF unavailable |
| 29 | Lecture 29: Diffusion | PDF unavailable |
| 30 | Lecture 30: Continuity Equation | PDF unavailable |
| 31 | Lecture 31: Resistor and diode (p-n junction) | PDF unavailable |
| 32 | Lecture 32: Fundamentals of p-n junction | PDF unavailable |
| 33 | Lecture 33: Fundamentals of p-n junction contd. | PDF unavailable |
| 34 | Lecture 34: Solar cells | PDF unavailable |
| 35 | Lecture 35: Microelectronics processing | PDF unavailable |
| 36 | Lecture 36: MOS capacitor | PDF unavailable |
| 37 | Lecture 37: Transistor | PDF unavailable |
| 38 | Lecture 38: Organic Electronics | PDF unavailable |
| 39 | Lecture 39: Organic Light Emitting Diodes | PDF unavailable |
| 40 | Lecture40: Organic Solar Cells and Organics Thin Film Transistors | PDF unavailable |