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Faculty of Science Handbook, Session 2019/2020
Soft-skills: Assessment Method:
CS3, CT3, LL2 Final Examination: 60%
Continuous Assessment: 40%
References:
1. Norman E. Dowling, Mechanical Behavior of Materials, 3rd Edition Medium of Instruction:
(2006) English
2. James A. Jacobs and Thomas, Engineering Materials Technology:
Structures, Processing, Properties, and Selection, 5th Edition Soft-skills:
3. Keith J. Bowman, Introduction to Mechanical Behavior of Materials, CS2, CT3, LL2
(2003)
References:
1. R.E. Hummel, Electronic Properties of Materials (Springer, 2000)
SMEB2201 QUANTUM MECHANICS FOR MATERIALS SCIENCE 2. D.C. Jiles, Introduction to the Electronic Properties of Materials
(CRC Press, 2001)
The foundations of quantum mechanics: Operators in quantum 3. L. Solymar, D. Walsh, Electrical Properties of Materials (Oxford
mechanics, The postulates of quantum mechanics, Hermitian operators, University Press, 2009)
The uncertainty principle, Matrices in quantum mechanics 4. S.O Kasap, Principles of Electronic Materials and Devices
Linear motion and the harmonic oscillator: the Schrodinger equation, (McGraw-Hill, 2001)
Translational motion, Penetration into and through barriers, Particle in a
box, The harmonic oscillator
Rotational motion and the hydrogen: Particle on a ring, Particle on a SMEB2203 OPTICAL PROPERTIES OF MATERIALS
sphere, Motion in a Coulombic field
Angular momentum: The angular momentum operators, The definition Nature of light: index of refraction, Ray Optics, polarized light, p and s
of the states, The angular momenta of composite systems waves,
Introduction to group theory Optical processes : absorption, transmission, reflection, Beer-Lambert
Techniques of approximation: Time-independent perturbation theory law, atomic electronic transition, molecular electronic transition,
Atomic spectra and atomic structure: An introduction to molecular electronic absorption in metal, semiconductor and insulator, electric
structure, The Born-Oppenheimer approximation, Molecular orbital polarisation, dispersion relations, normal dispersion, anomalous
theory, Molecular orbital theory of polyatomic molecules dispersion, Fresnel Equation, Total internal reflection. Snell’s law,
The calculation of electronic structure: Hartree-Fock self-consistent dielectric permittivity, optical dispersion, group velocity, phase velocity,
field method, Electron correlation, Density functional theory, Semi- optical activity, luminescence, fluorescence , phosphorescence,
empirical methods, Molecular rotations and vibrations, Molecular radiative lifetime, plasma frequency, reflection from metal, refraction
electronic transitions from metal, plasmons, birefringence
Examples of state of art materials science problem in advanced Optical coefficient: complex refractive index, attenuation, absorption
industry and scientific world solved by above concepts coefficient, skin depth,
Examples of state of the art of optical materials used in industry
Assessment Method:
Final Examination: 60% Assessment Method:
Continuous Assessment: 40% Final Examination: 60%
Continuous Assessment: 40%
Medium of Instruction:
English Medium of Instruction:
English
Soft-skills:
CS2, CT3, LL2 Soft-skills:
CS2, CT3, LL2
References:
1. D. Griffiths, Introduction to Quantum Mechanics (Prentice Hall, References:
2004) 1. M. Fox, Optical Properties of Solids (Oxford Series in Condensed
2. W. Greiner, Quantum Mechanics. An Introduction (Springer, 2008) Matter Physics (Oxford University Press, 2002)
3. R. Scherrer, Quantum Mechanics An Accessible Introduction 2. B.E.A Saleh, M.C Teich, Fundamentals of Photonics (Wiley Series
(Pearson Int’l Ed., 2006) in Pure and Applied Optics, (Wiley-Blackwell,2007)
4. Richard L. Liboff, Introductory Quantum Mechanics (Addison 3. R.J.D Tilley, Colour and The Optical Properties of Materials: An
Wesley, 2003) Exploration of the Relationship Between Light, the Optical
5. R. Eisberg & R. Resnick, Quantum Physics of Atoms, Molecules, Properties of Materials and Colour (Wiley, 2011)
Solids, Nuclei and Particles, 2nd ed (Wiley, 1985)
SMEB2204 MATERIALS CHARACTERISATION
SMEB2202 ELECTRICAL PROPERTIES OF MATERIALS
Structural, morphological, thermal, electrical, magnetic and mechanical,
Electrical Conduction in Metals: conductivity, drift velocity, mean free chemical characterisation of material:
path, Drude mode, Drude-Sommerfeld model, Matthiessen’s rule, work Light microscopy, x-ray diffraction, scanning probe microscopy ,
function, Thermionic emission, Schottky effect. scanning electron microscopy, transmission electron microscopy, UV-
Junction between two metals and its industrial application: contact VIS-NIR, auger electron spectroscopy, fast fourier transform infrared
potential, Seebeck coefficient, Peltier effect, Thermoelectric effect. spectroscopy, secondary ion mass spectroscopy, four-point probe,
Electrical Properties of semiconductor: valence bands, conduction thermogavimetry, differential scanning calorimetry , thermogravimetry,
band, Intrinsic Semiconductors, Fermi energy, Extrinsic electrical impedance spectroscopy, vibrating sample magnetometer.
Semiconductors, n-type semiconductors, donor, acceptor, band Basic operation, sample preparation and interpretation of data. Basic
structure, conductivity. failure analysis of materials using different characterization equipment.
Dielectric materials: polar, nonpolar materials, Debye Equation,
Dielectric breakdown (intrinsic, thermal and discharge), Assessment Method:
Piezoelectricity, Ferroelectricity and their state of the art application. Final Examination: 60%
Ionic conduction: conducting polymer, organic metals. Continuous Assessment: 40%
Medium of Instruction:
English
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