Page 32 - handbook 20152016
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Faculty of Science Handbook, Session 2015/2016
requirements, D.C analysis of the circuits and A.C analysis of the BJT Medium of Instruction:
circuit. English
Assessment Method: Soft-skills:
Final Examination: 60% CS3, CTPS3, LL2
Continuous Assessment: 40%
References:
Medium of Instruction: 1. Franz Mandl, Quantum Mechanics (John Wiley & Sons, 2013)
English 2. Albert Messiah, Quantum Mechanics (Dover Pubns, 2011)
3. Y.B. Band & Y vishal, Quantum Mechanics with Applications to
Soft-skills: Nanotechnology & Information Science (Elsevier Ltd, 2013)
CS2, CTPS2, CTPS3,LL1 4. D. Griffiths, Introduction to Quantum Mechanics (Prentice Hall,
2004)
References: 5. W. Greiner, Quantum Mechanics. An Introduction (Springer, 2008)
1. R. Boylestad & L. Nashelsky, Electronic Devices and Circuit
Theory, 11th ed. (Prentice Hall, 2012) SIF2002 ELECTROMAGNETISM I (3 CREDITS)
2. T.L. Floyd & D. Buchla, Electronics Fundamentals: Circuits, Electric charge, Coulomb’s law, continuous charge distribution, electric
Devices, and Applications (Prentice Hall, 2013) field, Gauss’s law, electric potential energy and potential, work done to
3. A.P. Malvino & D. Bates, Electronic Principles with simulation CD move charges, energy of point charge and continuous charge
(McGraw-Hill Education, 2015) distributions, conductors, induced charge.
4. A.J. Diefenderfer & B.E. Holton, Principles of Electronic Dielectrics, induced dipoles, polarization, bound charge, field in
Instrumentation, 3rd Edition (Saunders Coll. Publ., 1994) dielectrics; electric displacement, linear dielectrics, susceptibility,
permittivity and dielectric constant, forces and torques using the
SIF1006 PRACTICAL PHYSICS I (2 CREDITS) electrostatic energy, capacitors and capacitance, RC circuit and RCL
Experimental data analysis: precision and accuracy, significant figures, circuit.
systematic error, statistical error, propagation of uncertainties of Lorentz force law on charges and current in magnetic field and electric
measurement, uncertainty analysis, statistical analysis field, Biot-Savart law, steady current, magnetic field of steady current,
Physics experiments on the topics of mechanics Ampere’s law and displacement current.
Physics experiments on the topics of heat Magnetic dipoles, magnetic dipole moments, Diamagnet, paramagnet
Physics experiments on the topics of electricity and ferromagnet, magnetization, bound current, Ampére law in
Physics experiments on the topics of magnetism magnetized materials, magnetic susceptibility and permeability,
Physics experiments on the topics of optics and modern physics ferromagnetism, antiferromagnetism.
Electromotive force (emf), motional emf; Faraday’s law and Lenz’s law,
Assessment Method: electromagnetic induction, mutual inductance, self-inductance, energy
Final Examination: 60% in magnetic fields, displaced current, Maxwell’s equations.
Continuous Assessment: 40%
Assessment Method:
Medium of Instruction: Final Examination: 60%
English Continuous Assessment: 40%
Soft-skills: Medium of Instruction:
CS2, CTPS2, LL1, TS1, LS1 English
References: Soft-skills:
1. Douglas C. Montgomery, Introduction to Linear Regression CS2, CTPS2,CTPS3, LL2
Analysis, (Wiley, 2012)
2. S. V. Gupta , Measurement Uncertainties: Physical Parameters References:
and Calibration of Instruments Hardcover , (Springer, 2012) 1. S. Grant and W. R. Phillips, Electromagnetism, 2nd ed. (Wiley,
3. D. V. Skobel tsyn, Experimental Physics: Methods and Apparatus 1990)
(The Lebedev Physics Institute Series) (Springer, 2012) 2. E. M. Purcell, D. J. Morin, Electricity and Magnetism, 3 ed.
rd
4. J.R. Taylor, An Introduction to Error Analysis (University Science, (Cambridge University Press, 2013)
1997) 3. J. Reitz, F. Milford, R. Christy, Foundations of Electromagnetic
5. N.C. Barford, Experimental Measurements: Precision, Error and theory, 4th ed. (Pearson, 2008)
Truth (Wiley, 1991). 4. David K. Cheng, Fundamentals of Engineering Electromagnetics,
Rev. ed., (Pearson, 2013)
LEVEL 2 5. W. K. H. Panofsky, M. Phillips, Classical Electricity and
nd
SIF2001 QUANTUM MECHANICS I (3 CREDITS) Magnetism, 2 ed. (Addison-Wesley, 2012)
Basic principles: wave packets, eigen functions, superposition SIF2003 ELECTROMAGNETISM II (3 CREDITS)
principles, quantum mechanical postulates and probability density, Revision on electricity and magnetism in derivative forms. Coordinate
uncertainty in measurements, Heisenberg uncertainty principles, space
representation and momentum representation, measurement effect, systems: cylindrical, rectangle and spherical coordinates, Divergence
commutators and constant of motion, equation of flux continuity, theorem and Stokes’ theorem, imaging method, Gauss theorem in
derivative form, divergence and curl of magnetic field, Laplace equation
probability, Ehrenfest theorem. in 2 and 3 dimensions, boundary conditions and theorem of
Time independent Schroedinger equation: free particle, step potential, uniqueness, boundary conditions for D, E, B and H vectors, Free and
square well potential and barrier potential, Harmonic oscillator.
Hydrogen atom: quantum mechanics in 3-D, solution of Schroedinger bounded charges, Field variation with time, Maxwell’s equations in
equation, quantum numbers, eigen values and degenerates. differential and integral forms, Solution to Maxwell’s equations in free
space, Maxwell equations in matter, Scalar potential, vector potential
Angular momentum: angular momentum operators, orbital magnetic and Gauge transformation. Electromagnetic waves: In free space,
moment, spin and total angular momentum. polarization, reflection and transmission in medium, Helmholtz’s
Assessment Method: equation.
Final Examination: 60% Electromagnetic wave propagation: Poynting theorem and Poynting
Continuous Assessment: 40% vector, electromagnetic wave in conducting and nonconducting
medium, frequency dependence of permittivity and conductivity,
dispersion in nonconducting medium, propagation of electromagnetic
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