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Syllabus
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Engineering Physics-2 Syllabus
(2 pages)
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DIFFRACTION
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Details of Engineering Physics 2 Syllabus | Diffraction of Light
12:00
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Various Phenomenon Associated With Light
13:00
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Types of Diffraction: Fresnel Vs Fraunhofer
14:00
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Concept of path & Phase difference
8:00
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Diffraction: Fraunhoffer diffraction at single slit
42:00
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Numerical Solving: Fraunhoffer Single Slit Diffraction
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Position of Maxima & Minima in Fraunhoffer Diffraction
17:00
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Dependency of Spectrum on Wavelength and Slit Width
9:00
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Width of Central Maxima
5:00
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Diffraction Grating: Derivation of Intensity
23:00
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Position of Maxima & Minima: Diffraction Grating
33:00
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Determination of wavelength of light using plane transmission grating
11:00
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Resolving power of a grating
16:00
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DIFFRACTION FULL CHAPTER
(33 pages)
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Numerical on Single Slit Diffraction
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RELATIVITY
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Relativity | Engineering Physics | #MU #SEM 2
10:00
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Prerequisites: Cartesian co-ordinate system, Special theory of Relativity & Inertial and Non-inertial Frames of reference
56:00
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Michelson Morley Experiment: Part 1
48:00
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Michelson Morley Experiment: Part 2 & Galilean transformations
22:00
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Lorentz Transformation
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time dilation +length contraction+energy mass relation+relativity numerical combine
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Relativity Notes
(32 pages)
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LASER AND FIBRE OPTICS
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LASER COMPLETE THEORY
(18 pages)
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Laser: spontaneous emission and stimulated emission
32:00
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Einsteins Equations
17:00
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Population inversion & Types of Pumping
18:00
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Levels of pumping
6:00
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Components of a Laser: Active medium. Resonantor Cavity, Pumping source
13:00
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Helium Neon laser
15:00
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Semiconductor Diode Laser
8:00
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Nd:YAG laser
5:00
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Applications of laser- Holography
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introduction to optical fiber
6:00
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Concept of total inernal reflection
6:00
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Angle of acceptance and Numerical Aperture
22:00
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OPTICAL FIBRE COMPLETE NOTES
(15 pages)
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V number
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number of modes of propagation
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types of optical fibres
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Fibre optic communication system
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ELECTRODYNAMICS
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Live 1: Concept of Scalar & Vector Field, Gradient, divergence & Curl
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Curl, Divergence & Gradient
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Physical Significance of Divergence, Gradient & Curl
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curl and divergence in Cartesian co-ordinate system
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Gauss‘s law for electrostatics
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Gauss‘s law for magnetostatics
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Faraday‘s Law and Ampere‘s circuital law
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Maxwell‘s equations (Free space and time varying fields)
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Electrodynamics Complete Notes
(19 pages)
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NANOTECHNOLOGY
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NANOTECHNOLOGY NOTES
(13 pages)
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Prerequisites : Scattering of electrons, Tunneling effect, Electrostatic focusing, magneto static focusing
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Nanomaterials : Properties (Optical, electrical, magnetic, structural, mechanical) and applications
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Surface to volume ratio
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Two main approaches in nanotechnology -Bottom up technique and Top down technique
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Tools for characterization of Nanoparticles: Scanning Electron Microscope (SEM)
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Transmission Electron Microscope (TEM)
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Atomic Force Microscope (AFM)
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Methods to synthesize Nanomaterials: Ball milling
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Sputtering
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Vapour deposition
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Solgel
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