Metallurgical-Physics of Materials (English)

   Thursday, February 20, 2025   

Starting a new Lecture Notes Series on Metallurgical-Physics of Materials

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Metallurgical-Physics of Materials By Lecture Notes together!

Lecture 1: Introduction

Lecture 2: Properties of Materials

Lecture 3: Thermal Expansion

Lecture 4: Measuring Electrical Conductivity: DC and AC

Lecture 5: Free Electron Gas

Lecture 6: The Ideal Gas

Lecture 7: Drude Model: Electrical Conductivity

Lecture 8: Drude Model: Thermal Conductivity

Lecture 9: Drude Model: Successes and Limitations

Lecture 10: Drude Model: Source of Shortcomings

Lecture 11: Large Systems and Statistical Mechanics

Lecture 12: Maxwell Boltzmann Statistics

Lecture 13: Classical Particles and Quantum Particles

Lecture 14: Mod-02 Lec-14 History of Quantum Mechanics-1

Lecture 15: History of Quantum Mechanics \u20ac\u201c 2

Lecture 16: Introduction to Drude Sommerfeld model

Lecture 17: Fermi-Dirac Statistics: Part 1

Lecture 18: Fermi-Dirac Statistics: Part 2

Lecture 19: Features of the Fermi Dirac Distribution Function

Lecture 20: Maxwell-Boltzmann Distribution Vs Fermi-Dirac Distribution

Lecture 21: Anisotropy and Periodic Potential in a Solid

Lecture 22: Confinement and Quantization: Part 1

Lecture 23: Confinement and Quantization: Part 2

Lecture 24: Density of States

Lecture 25: Fermi Energy, Fermi Surface, Fermi Temperature

Lecture 26: Mod-02 Lec-26 Electronic Contribution to Specific Heat at Constant Volume

Lecture 27: Reciprocal Space 1: Introduction to Reciprocal Space

Lecture 28: Reciprocal Space 2: Condition for Diffraction

Lecture 29: Reciprocal Space 3: Ewald sphere, Simple Cubic, FCC and BCC in Reciprocal Space

Lecture 30: Wigner Seitz Cell and Introduction to Brillouin Zones

Lecture 31: Brillouin Zones, Diffraction, and Allowed Energy Levels

Lecture 32: E Vs k, Brillouin Zones and the Origin of Bands

Lecture 33: Calculating Allowed Energy Bands and Forbidden Band Gaps

Lecture 34: Bands; Free Electron Approximation, Tight Binding Approximation

Lecture 35: Semiconductors

Lecture 36: Magnetic Properties

Lecture 37: Electron Compounds; Phonons, Optoelectronic Materials

Lecture 38: Superconductivity

Lecture 39: Bose-Einstein Statistics

Lecture 40: Physics of Nano Scale Materials; Course Summary