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  • Wave Mechanics and X-ray Diffraction
    • introduction to wave mechanics
    • de-Broglie matter waves
    • THE SCHRIODINGER EQUATION
    • Wave-Particle Duality
    • Phase and group velocity
    • Bragg’s law
    • Davisson-Germer Experiment
    • Crystal structure of Diamond
    • Physical significance of wave function
    • Crystal structure of NaCl
    • Paritcle in a 1D-box
    • Packing factor
    • Principles of X-ray Diffraction
    • Bragg’s spectrometer
    • Compton Effect
    • Experimental verification:Compton Effect

  • Dielectric and Magnetic Properties of Materials
    • Introduction to Modern Physics
    • Ultrasonic Production
    • Photo-electric effect
    • Piezoelectric effect
    • The Compton effect
    • Piezoelectric generator
    • Detection of Ultrasonic Waves
    • De Broglie hypothesis
    • Acousing Grating
    • Extension to electron particle-davisson and german experiment
    • application of ultrasonics
    • Phase velocity and group velocity
    • Ultrasonic Cleaning applications
    • Relation between group velocity and particle velocity
    • Dielectric Constant
    • Expression for De Broglie wavelength using group velocity
    • Dielectric constant and polarizability
    • Characteristics of matter wave
    • Sources of polarizability
    • Piezoelectricity
    • Ferroelectricity
    • Dielectric Loss
    • Langevin’s theory for diamagnetic material
    • Langevins Theory of Paramagnetism

  • Electromagnetism
    • Magnetic Field
    • The Lorentz Force
    • Motion in a crossed electric and magnetic fields
    • Force on a Current Carrying Conductor
    • Torque on a Current Loop in a Uniform Magnetic Field
    • Potential Energy of a Magnetic Dipole
    • Biot- Savarts' Law
    • Amperes Law
    • Vector Potential
    • Electromagnetic Induction
    • Motional Emf
    • Time Varying Field
    • Mutual Inductance
    • Self Inductance
    • Magnetism in Matter
    • Ferromagnets
    • Diamagnetism:Displacement Current
    • Maxwell's Equations
    • Electromagnetic Waves
    • Generation of Electromagnetic Waves
    • Poynting Vector

  • Superconductivity and Science and Technology of Nanomaterials
    • Classical free Electron theory
    • Superconductivity and Optical Fibers
    • Introduction: Evidence of a Phase Transition
    • Drift velocity
    • Meissner effect
    • Meissner effect
    • Expression for electrical conductivity in metals
    • Types of superconductors
    • The magnetic properties of superconductors
    • Wave-particle duality
    • Effect of impurity and temperature on electrical resistivity of metals
    • Expression for Interplanar spacing
    • Type I and Type II Superconductors
    • Failure of classical free electron theory
    • Mechanism of superconductivity
    • Quantum free electron theory
    • BCS theory and Cooper pairs
    • Fermi-dirac statistics
    • High – Tc superconductors
    • Fermi energy and fermi factor
    • Applications of superconductors
    • Density of states
    • The Importance of Nanoscale
    • Buckyballs
    • Ongoing Research and Development Activities
    • Applications of nanotechnology

Branch : First Year-Engineering Syllabus | Subject : Physics-II
Wave Mechanics and X-ray Diffraction
  • Bragg’s law

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  • Crystal structure of Diamond

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  • Crystal structure of NaCl

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  • Packing factor

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  • introduction to wave mechanics

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  • de-Broglie matter waves

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  • THE SCHRIODINGER EQUATION

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  • Wave-Particle Duality

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  • Phase and group velocity

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  • Davisson-Germer Experiment

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  • Physical significance of wave function

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  • Paritcle in a 1D-box

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  • Principles of X-ray Diffraction

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  • Bragg’s spectrometer

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  • Compton Effect

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  • Experimental verification:Compton Effect

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