Page 228 - Handbook Bachelor Degree of Science Academic Session 20202021
P. 228
Faculty of Science Handbook, Academic Session 2020/2021
References:
1. Allen J. Bard and Larry R. Faulkner , Electrochemical Methods:
Fundamentals and Applications , 2 Edition (Wiley, 2001)
nd
2. John O'M. Bockris, Amulya K.N. Reddy and Maria E. Gamboa-
Aldeco, Modern Electrochemistry 2A: Fundamentals of
Electrodics, Volume 2 (Springer, 2001)
3. John Newman and Karen E. Thomas-Alyea, Electrochemical
Systems, 3rd Edition (Wiley, 2004)
SMEB4302 ADVANCED MATERIALS PROCESSING
TECHNOLOGY
Physical process: Thermal vacuum deposition, e-beam sputtering,
plasma etching, plasma cleaning and conditioning , chemical vapour
deposition, Metal –organic vapour phase epitaxy, molecular-beam
epitaxy, vacuum pressure impregnation, micro-nano-laser fabrication
and processing,
Chemical process: sol-gel processing, hydrothermal, solvothermal,
ionothermal, self-assembly assisted method, pyrolysis, radiation
assisted method
Basic processing of bulk ceramic: Preparation of polymers and glass
Fabrication methods, diffusion, ion implantation, lithography,
metallization.
Invitation from industry to give a presentation on Advanced Materials
Processing Technology in his/her company.
Assessment Method:
Final Examination: 50%
Continuous Assessment: 50%
Medium of Instruction:
English
Soft-skills:
CS2, CT3, LL2
References:
1. Thin-Film Deposition: Principles and Practice by Donald Smith
2. Handbook of Physical Vapor Deposition (PVD) Processing
(Materials Science and Process Technology) by Donald M. Mattox
3. Advanced Ceramic Processing & Technology (Materials Science
and Process Technology)
SMEB4303 COMPUTATION AND SIMULATION
This course explores the basic concepts of computer modelling and
simulation in science and engineering. We'll use techniques and
software for simulation, data analysis and visualization. Continuum,
mesoscale, atomistic and quantum methods are used to study
fundamental and applied problem in materials science. Examples
drawn from the multi-disciplines are used to understand or characterize
complex structures of materials and complement experimental
observations.
Assessment Method:
Final Examination: 50%
Continuous Assessment: 50%
Medium of Instruction:
English
Soft-skills:
CS3, CT3, LL2
References:
1. Alan Hinchliffe, Molecular modelling for beginners (Wiley 2003)
2. Mauro Ferrario, Giovanni Ciccotti, Kurt Binder, Ettore Majorana
Foundation and Center for Scientific Culture, Computer
simulations in condensed matter systems: from materials to
chemical biology, Volume 1 (Springer 2006)
3. Tamar Schlick, Molecular Modeling and Simulation: An
Interdisciplinary Guide (Springer 2010)
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