Page 241 - handbook 20162017

P. 241

Faculty of Science Handbook, Session 2016/2017

Soft-skills: References:
CS3, CT3, LL2 1. L.C. Cullity, C.D. Graham, Introduction to Magnetic Materials
(Addison-Wesley,1972)
References: 2. University Joseph Fourier, Magnetism: Fundamentals, (Springer,
1. S.T. Thornton & A. Rex, Modern Physics for Scientists and 2004)
Engineers, 3rd ed. (Brooks Cole, 2005) 3. R.C. O’Handley, Modern Magnetic Materials Principles (Wiley-
2. R.A. Serway, C.J. Moses, C.A. Moyer, Modern Physics, 3 ed. Interscience, 1999)
rd
(Saunders, 2005) 4. M. Tinkham, Introduction to Superconductivity, 2nd ed. (Dover,
3. A. Beiser, Concepts of Modern Physics, 6 ed. (McGraw-Hill, 2004).
th
2002)
4. K. Krane, Modern Physics, 2 ed. (Wiley, 1996) SMEB2102 MECHANICAL PROPERTIES OF MATERIALS
nd
5. R. Eisberg & R. Resnick, Quantum Physics of Atoms, Molecules, Mechanical Response: Tensile Strength, Tensile Stress, Stiffness in
Solids, Nuclei & Particles, 2nd ed. (Wiley, 1985) Tension, Young's Modulus. Poisson Effect, Shearing Stress and strain,
Stress-Strain Curve
Thermodynamics of Mechanical Responses: Enthalpic Response,
LEVEL 2 Entropic Response, Viscoelasticty
Yield and Plastic Flow: Multiaxial Stress states, Effect of Hydrostatic
SMES2205 STATISTICAL PHYSICS Pressure, Effect of rate and Temperature, Continuum Plasticity,
Summary of thermodynamics. Thermodynamics formulation in Dislocation basis of yield and creep, kinetics of creep in crystalline
materials
statistical terms, application of canonical ensemble approach with Fracture: Atomistic of Creep Rupture, Fracture Mechanics- The energy
examples related to paramagnetic solid and specific heat capacity of approach and the Stress intensity Approach ,Fatigue
solid, distribution of classical and quantum particles, Maxwell-
Boltzmann distribution and the perfect classical gas, quantum perfect Materials design for high performance mechanical materials for
gas, Bose-Einstein and Fermi-Dirac distributions. Applications: phonon industrial and civil applications
in solid, photon and black body radiation, low temperature physics. Assessment Method:
Shannon information theory, entropy, collective entropy, Final Examination: 60%
communication line. Continuous Assessment: 40%
Assessment Method:
Final Examination: 60% Medium of Instruction:
English
Continuous Assessment: 40%
Soft-skills:
Medium of Instruction: CS3, CT3, LL2
English
References:
Soft-skills: 1. Norman E. Dowling, Mechanical Behavior of Materials, 3rd Edition
CS2, CT3, LL2 (2006)
2. James A. Jacobs and Thomas, Engineering Materials Technology:
References:
1. F. Reif, Fundamentals of Statistical and Thermal Physics Structures, Processing, Properties, and Selection, 5th Edition
(Waveland Pr Inc, 2008) 3. Keith J. Bowman, Introduction to Mechanical Behavior of
2. Silvio R.A. Salinas, Introduction to Statistical Physics (Springer, Materials, (2003)
2010)
3. R. Bowley and M. Sanchez, Introductory Statistical Mechanics SMEB2201 QUANTUM MECHANICS FOR MATERIALS SCIENCE
(Oxford Science Publ., 2002)
4. F. Mandl, Statistical Physics, 2 ed. (Wiley, 1988) The foundations of quantum mechanics: Operators in quantum
nd
mechanics, The postulates of quantum mechanics, Hermitian
operators, The uncertainty principle, Matrices in quantum mechanics
SMEB2101 MAGNETIC AND SUPERCONDUCTOR PROPERTIES Linear motion and the harmonic oscillator: the Schrodinger
equation, Translational motion, Penetration into and through barriers,
OF MATERIALS
The course covers the bipolar and field effect transistor Basic concept Particle in a box, The harmonic oscillator
of magnetism: susceptibility, permeability, magnetic induction, Rotational motion and the hydrogen: Particle on a ring, Particle on a
sphere, Motion in a Coulombic field
magnetization, magnetic moment. Angular momentum: The angular momentum operators, The
Diamagnetism: definition of the states, The angular momenta of composite systems
Paramagnetism: Curie constant, Curie–Weiss law, Hund’s rule Introduction to group theory
Ferromagnetism: remanence, coercive field, hysteresis, Curie
temperature Techniques of approximation: Time-independent perturbation theory
Piezomagnetism; magnetostriction, magnetic domains; Kerr effect, Atomic spectra and atomic structure: An introduction to molecular
structure, The Born-Oppenheimer approximation, Molecular orbital
Barkhausen effect theory, Molecular orbital theory of polyatomic molecules
Superconductor: Meissner Effect, London penetration depth, The calculation of electronic structure: Hartree-Fock self-consistent
Josephson effect
Type of magnets and materials; Application of Magnetic materials field method, Electron correlation, Density functional theory, Semi-
: Magnetic resonance imaging, hard discs, giant magnetoresistance, empirical methods, Molecular rotations and vibrations, Molecular
electronic transitions
superconducting quantum interference device spintronics
Examples of state of art materials science problem in advanced
Assessment Method: industry and scientific world solved by above concepts
Final Examination: 60%
Continuous Assessment: 40% Assessment Method:
Final Examination: 60%
Medium of Instruction: Continuous Assessment: 40%
English
Medium of Instruction:
oft-skills: English
CS2, CT3, LL2
Soft-skills:
CS2, CT3, LL2
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