Why this course?

Description

This course is made on demand for students belonging to different Universities.

In this course, We have combined syllabus of All Major universities like - Mumbai, Pune and so on.

SO before purchasing this course, Please check the syllabus of your university and Compare it with this course.

I have included 18 units in this course! Yes 18 UNITS, Literally All universities have 6 units in their semeseter course, So check and compare your 6 units with our 18 units provided.

Syllabus of Course - Units Description

1) Quantum Physics/Quantum Mechanics

2) Crystallography

3) Interference in thin films

4) Semiconductor Devices

5) Superconductors and Super capacitors

6) Laser and Fibre Optics

7) Diffraction

8) Electrodynamics

9) Theory of Relativity

10) Physics of Sensors

11) Nano Technology

12) Wave Optics

13) Magnetism and Superconductivity

14) Non Destructive Testing and Nano Technology

15) Electrostatics

16) Magnetostatics

17) Vector Calculus

18) Electric Field and Electric Potential

So there are the units included in this course, If these units are there in this course, You can proceed ahead. Also this course is recorded course, Everything and full content with Notes, Lectures, will be available to you As soon as you purchase the course, and is valid till 6 months from Date of your purchase. This is passive course.

 

Syllabus in Depth - 

1) QUANTUM PHYSICS (Prerequisites : Dual nature of radiation, Photoelectric effect Matter waves-wave nature of particles, de-Broglie relation, Davisson-Germer experiment)  De Broglie hypothesis of matter waves; properties of matter waves; wave packet, phase velocity and group velocity; Wave function; Physical interpretation of wave function; Heisenberg uncertainty principle; non existence of electron in nucleus; Schrodinger’s time dependent wave equation; time independent wave equation; Particle trapped in one dimensional infinite potential well, Quantum Computing.

 

2) CRYSTALLOGRAPHY - All Basics, Miller indices; interplanar spacing; X-ray diffraction and Bragg’s law; Determination of Crystal structure using Bragg’s diffractometer;

3) SEMICONDUCTOR PHYSICS -Intrinsic and extrinsic semiconductors, Energy bands in conductors, semiconductors and insulators, Semiconductor diode, I-V characteristics in forward and reverse bias) Direct & indirect band gap semiconductor; Fermi level; Fermi dirac distribution; Fermi energy level in intrinsic & extrinsic semiconductors; effect of impurity concentration and temperature on fermi level; mobility, current density; Hall Effect; Fermi Level diagram for p-n junction (unbiased, forward bias, reverse bias); Applications of semiconductors: LED, Zener diode, Photovoltaic cell.

4) INTERFERENCE IN THIN FILM - Wave front and Huygen's principle, reflection and refraction, Interference by division of wave front, Youngs double slit experiment) Interference by division of amplitude, Interference in thin film of constant thickness due to reflected and transmitted light; origin of colours in thin film; Wedge shaped film; Newton’s rings. Applications of interference - Determination of thickness of very thin wire or foil; determination ofrefractive index of liquid; wavelength of incident light; radius of curvature of lens; testing of surfaceflatness; Anti-reflecting films and Highly reflecting film. 

5) SUPERCONDUCTORS AND SUPERCAPACITORS (Prerequisites : Electric current, flow of electric charges in a metallic conductor, drift velocity, mobility and their relation with electric current, Ohm's law, electrical resistance, V-I characteristics (linear and non-linear), electrical resistivity and conductivity temperature dependence of resistance) Superconductors: Critical temperature, critical magnetic field, Meissner’s effect, Type I and Type II and high Tc superconductors; Supercapacitors: Principle, construction, materials and applications, comparison with capacitor and batteries : Energy density, Power density,

06) Laser & Fibre Optics - 

Laser - Basics of laser and its mechanism, characteristics of laser - Semiconductor laser: Single Hetro-junction laser - Gas laser: CO2 laser - Applications of lasers: Holography, IT, industrial, medical Optic Fiber - Introduction, parameters: Acceptance Angle, Acceptance Cone, Numerical Aperture - Types of optical fiber- step index and graded index - Attenuation and reasons for losses in optic fibers (qualitative) - Communication system: basic building blocks Advantages of optical fiber communication over conventional methods.

7) Diffraction -- Wave front and Huygen's principle, reflection and refraction, diffraction, Fresnel diffraction and Fraunhoffer diffraction) 04 University of Mumbai, First Year Engineering, (Common for all Branches of Engineering) REV2019 ‘C’ Scheme 38/61 Diffraction: Fraunhoffer diffraction at single slit, Diffraction Grating, Resolving power of a grating; Applications of diffraction grating; Determination of wavelength of light using plane transmission grating

8) Electrodynamics- Electric Charges, Coulomb's law-force between two point charges, Electric field, electric field due to a point charge, electric field lines, electric dipole, electric field due to a dipole, Gauss's law, Faraday’s law) Scalar and Vector field, Physical significance of gradient, curl and divergence in Cartesian co-ordinate system, Gauss’s law for electrostatics, Gauss’s law for magnetostatics, Faraday’s Law and Ampere’s circuital law; Maxwell’s equations (Free space and time varying fields).

 

9) Theory of Relativity - 

-Cartesian co-ordinate system) Special theory of Relativity: Inertial and Non-inertial Frames of reference, Galilean transformations, Lorentz transformations (space – time coordinates), Time Dilation, Length Contraction and Mass-Energy relation.

 

10) Physics of Sensors

-Transducer concept, meaning of calibration, piezoelectric effect) Resistive sensors: a) Temperature measurement: PT100 construction, calibration, b) Humidity measurement using resistive sensors, Pressure sensor: Concept of pressure sensing by capacitive, flex and inductive method, Analog pressure sensor: construction working and calibration and applications. Piezoelectric transducers: Concept of piezoelectricity, use of piezoelectric transducer as ultrasonic generator and application of ultrasonic transducer for distance measurement, liquid and air velocity measurement. Optical sensor: Photodiode, construction and use of photodiode as ambient light measurement and flux measurement. Pyroelectric sensors: Construction and working principle, application of pyroelectric sensor as bolometer.

 

11) Nanotechnology - Nanomaterials : Properties (Optical, electrical, magnetic, structural, mechanical) and applications, Surface to volume ratio; Two main approaches in nanotechnology -Bottom up technique and Top down technique; Tools for characterization of Nanoparticles: Scanning Electron Microscope (SEM), Transmission Electron Microscope (TEM), Atomic Force Microscope (AFM). Methods to synthesize Nanomaterials: Ball milling, Sputtering, Vapour deposition, Solgel

 

12) Wave optics -

Interference - Introduction to electromagnetic waves and electromagnetic spectrum - Interference in thin film of uniform thickness (with derivation) - Interference in thin film wedge shape (qualitative) - Applications of interference: testing optical flatness, anti-reflection coating Diffraction - Diffraction of light - Diffraction at a single slit, conditions for principal maxima and minima, diffraction pattern - Diffraction grating, conditions for principal maxima and minima starting from resultant amplitude equations, diffraction pattern - Rayleigh’s criterion for resolution, resolving power of telescope and grating Polarization - Polarization of light, Malus law - Double refraction, Huygen’s theory of double refraction Applications of polarization: LCD

 

13) Magentism and Superconductivity

Magnetism - Origin of magnetism - Classification of magnetism on the basis of permeability (qualitative) - Applications of magnetic devices: transformer cores, magnetic storage, magneto-optical recording Superconductivity - Introduction to superconductivity; Properties of superconductors: zero electrical - resistance, critical magnetic field, persistent current, Meissner effect - Type I and Type II superconductors - Low and high temperature superconductors (introduction and qualitative) - AC/DC Josephson effect; SQUID: basic construction and principle of working; Applications of SQUID - Applications of superconductors

14) Non Destructive Testing and Nano Technology

Magnetism - Origin of magnetism - Classification of magnetism on the basis of permeability (qualitative) - Applications of magnetic devices: transformer cores, magnetic storage, magneto-optical recording Superconductivity - Introduction to superconductivity; Properties of superconductors: zero electrical - resistance, critical magnetic field, persistent current, Meissner effect - Type I and Type II superconductors - Low and high temperature superconductors (introduction and qualitative) - AC/DC Josephson effect; SQUID: basic construction and principle of working; Applications of SQUID - Applications of superconductors

15) Vector Calculus - 

Concept of Field, Scalar and Vector Point Function, Concept of gradient, Divergence and Curl in detail, Line integration, Surface integration and volume integration, Cyclindrical Coordinate system, Fundamental theorem on Gradient, Divergence and Curl, Also Reffered to as Stokes theorem, Greens Theorem

16) Electrostatics - Electric Field, Lines of Force, Electric Flux, ,Gauss Law, Applications of Gauss law, Conservative Fields, Potential, Poissons and Laplace equation, Uniqueness theorem, , Potential due to electric dipole, Torque and force acting on a dipole,, Potential energy of system of charges, Conductors in electrostatic field.

17) Magnetostatics - 

Basics of magnetism, Biot savarts Law, Current loop as dipole, Amperes Law , Solenoid, toroid, Properties of magnetic field - Curl and Divergence, Properties of Magnetic field part 2, Torque on current loop, Ballistic galvanometer, concept of decrement

 

18) Electric Field and electric Potential -

Electric fields in matter,Polarization, Electric Susceptibility,Capacitors with and without dielectric, Displacement vector, Gauss Law, Magnetization, Bound Currents, Auxillary Field, Relations between Quantities,Faradays Law, Reciprocation theorem, Energy Stored in magnetic field

 

If your syllabus Matches with these units, - Either full, half etc

Then you can proceed to buy this course.