Page 223 - Handbook Bachelor Degree of Science Academic Session 20202021
P. 223
Faculty of Science Handbook, Academic Session 2020/2021
References: Soft-skills:
1. L.C. Cullity, C.D. Graham, Introduction to Magnetic Materials CS2, CT3, LL2
(Addison-Wesley,1972)
2. University Joseph Fourier, Magnetism: Fundamentals, (Springer, References:
2004) 1. D. Griffiths, Introduction to Quantum Mechanics (Prentice Hall,
3. R.C. O’Handley, Modern Magnetic Materials Principles (Wiley- 2004)
Interscience, 1999) 2. W. Greiner, Quantum Mechanics. An Introduction (Springer, 2008)
4. M. Tinkham, Introduction to Superconductivity, 2nd ed. (Dover, 3. R. Scherrer, Quantum Mechanics An Accessible Introduction
2004). (Pearson Int’l Ed., 2006)
4. Richard L. Liboff, Introductory Quantum Mechanics (Addison
Wesley, 2003)
SMEB2102 MECHANICAL PROPERTIES OF MATERIALS 5. R. Eisberg & R. Resnick, Quantum Physics of Atoms, Molecules,
Solids, Nuclei and Particles, 2nd ed (Wiley, 1985)
Mechanical Response: Tensile Strength, Tensile Stress, Stiffness in
Tension, Young's Modulus. Poisson Effect, Shearing Stress and strain,
Stress-Strain Curve SMEB2202 ELECTRICAL PROPERTIES OF MATERIALS
Thermodynamics of Mechanical Responses: Enthalpic Response,
Entropic Response, Viscoelasticty Electrical Conduction in Metals: conductivity, drift velocity, mean free
Yield and Plastic Flow: Multiaxial Stress states, Effect of Hydrostatic path, Drude mode, Drude-Sommerfeld model, Matthiessen’s rule, work
Pressure, Effect of rate and Temperature, Continuum Plasticity, function, Thermionic emission, Schottky effect.
Dislocation basis of yield and creep, kinetics of creep in crystalline Junction between two metals and its industrial application: contact
materials potential, Seebeck coefficient, Peltier effect, Thermoelectric effect.
Fracture: Atomistic of Creep Rupture, Fracture Mechanics- The energy Electrical Properties of semiconductor: valence bands, conduction
approach and the Stress intensity Approach ,Fatigue band, Intrinsic Semiconductors, Fermi energy, Extrinsic
Materials design for high performance mechanical materials for Semiconductors, n-type semiconductors, donor, acceptor, band
industrial and civil applications structure, conductivity.
Dielectric materials: polar, nonpolar materials, Debye Equation,
Assessment Method: Dielectric breakdown (intrinsic, thermal and discharge),
Final Examination: 60% Piezoelectricity, Ferroelectricity and their state of the art application.
Continuous Assessment: 40% Ionic conduction: conducting polymer, organic metals.
Medium of Instruction:
English
Assessment Method:
Soft-skills: Final Examination: 60%
CS3, CT3, LL2 Continuous Assessment: 40%
References: Medium of Instruction:
1. Norman E. Dowling, Mechanical Behavior of Materials, 3rd Edition English
(2006)
2. James A. Jacobs and Thomas, Engineering Materials Technology: Soft-skills:
Structures, Processing, Properties, and Selection, 5th Edition CS2, CT3, LL2
3. Keith J. Bowman, Introduction to Mechanical Behavior of
Materials, (2003) References:
1. R.E. Hummel, Electronic Properties of Materials (Springer, 2000)
2. D.C. Jiles, Introduction to the Electronic Properties of Materials
SMEB2201 QUANTUM MECHANICS FOR MATERIALS SCIENCE (CRC Press, 2001)
3. L. Solymar, D. Walsh, Electrical Properties of Materials (Oxford
The foundations of quantum mechanics: Operators in quantum University Press, 2009)
mechanics, The postulates of quantum mechanics, Hermitian 4. S.O Kasap, Principles of Electronic Materials and Devices
operators, The uncertainty principle, Matrices in quantum mechanics (McGraw-Hill, 2001)
Linear motion and the harmonic oscillator: the Schrodinger
equation, Translational motion, Penetration into and through barriers,
Particle in a box, The harmonic oscillator SMEB2203 OPTICAL PROPERTIES OF MATERIALS
Rotational motion and the hydrogen: Particle on a ring, Particle on a
sphere, Motion in a Coulombic field Nature of light: index of refraction, Ray Optics, polarized light, p and s
Angular momentum: The angular momentum operators, The waves,
definition of the states, The angular momenta of composite systems Optical processes : absorption, transmission, reflection, Beer-Lambert
Introduction to group theory law, atomic electronic transition, molecular electronic transition,
Techniques of approximation: Time-independent perturbation theory electronic absorption in metal, semiconductor and insulator, electric
Atomic spectra and atomic structure: An introduction to molecular polarisation, dispersion relations, normal dispersion, anomalous
structure, The Born-Oppenheimer approximation, Molecular orbital dispersion, Fresnel Equation, Total internal reflection. Snell’s law,
theory, Molecular orbital theory of polyatomic molecules dielectric permittivity, optical dispersion, group velocity, phase velocity,
The calculation of electronic structure: Hartree-Fock self-consistent optical activity, luminescence, fluorescence , phosphorescence,
field method, Electron correlation, Density functional theory, Semi- radiative lifetime, plasma frequency, reflection from metal, refraction
empirical methods, Molecular rotations and vibrations, Molecular from metal, plasmons, birefringence
electronic transitions Optical coefficient: complex refractive index, attenuation, absorption
Examples of state of art materials science problem in advanced coefficient, skin depth,
industry and scientific world solved by above concepts Examples of state of the art of optical materials used in industry
Assessment Method: Assessment Method:
Final Examination: 60% Final Examination: 60%
Continuous Assessment: 40% Continuous Assessment: 40%
Medium of Instruction: Medium of Instruction:
English English
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