Page 243 - handbook 20162017

P. 243

Faculty of Science Handbook, Session 2016/2017

Superposition of time-temperature, WLF equation. Special applied 2. Sam Zhang, Lin Li, Ashok Kumar Materials Characterization
polymer, conducting polymer. Technological importance polymers. Techniques, 1 edition (CRC Press, Disember 22, 2008)
st
Assessment Method: 3. Angelika H. Hofmann, Scientific Writing and Communication:
Final Examination: 60% Papers, Proposals, and Presentations, 1 edition (Oxford University
Continuous Assessment: 40% Press, Disember 16, 2009)
Medium of Instruction: LEVEL 3
English
SMEB3271 MATERIAL SCIENCE LABORATORY II
Soft-skills:
CS2, CT3, LL2, EM1 Students are attached to research labs carrying out mini-projects on
experiments in material science in characterizing electrical, optical,
References: magnetic, mechanical, thermal properties of photonic materials, smart
materials electrochemistry, polymer composites, semiconductor
1. J.L. Fried, Polymer Science and Technology, Prentice Hall, 1995.
2. N.G. McCrum, C.P. Buckley and C.B. Bucknall, Principles of materials organic electronics, devices and advanced material
Polymer Engineering, Oxford University Press, 1988. processing while learning to use various characterizing equipments
3. P.Painter and M.M Coleman, Fundamentals of Polymer Science such as scanning electron microscopy, micro-raman spectroscopy, UV-
VIS-NIR spectroscopy, Light microscopy, x-ray diffraction, scanning
(AN Introductory Text), Technomic probe microscopy, transmission electron microscopy, auger electron
4. D.J. Bower, An Introduction to Polymer Physics, Cambridge Univ. spectroscopy, fast fourier transform infrared spectroscopy, four-point
Press 2002. probe, thermogravimetry, differential scanning calorimetry, electrical
SMEB2207 COMPUTER PROGRAMMING impedance spectroscopy and simple material process technology.
Students will be exposed with labviews programming.
Students are equipped with the fundamentals of how the computer
works. The important components in a computer will be explained in
detail. Students are taught to perform computer programming using C Assessment Method:
language. The basic statements are discussed and the methodology is Continuous Assessment: 100%
shown. C++ will also be briefly introduced.
Medium of Instruction:
Assessment Method: English
Final Examination: 60%
Continuous Assessment: 40% Soft-skills:
CS2, CT3, LL2
Medium of Instruction:
English References:
1. Y. Leng, Materials Characterization: Introduction to Microscopic
Soft-skills: and Spectroscopic Methods, 1 edition (Wiley, Jun 2, 2008)
st
CS2, CT3, LL2 2. Sam Zhang, Lin Li, Ashok Kumar Materials Characterization
Techniques, 1 edition (CRC Press, Disember 22, 2008)
st
References: 3. Angelika H. Hofmann, Scientific Writing and Communication:
1. Richard Johnsonbaugh and Martin Kalin, C for Scientists and Papers, Proposals, and Presentations, 1 edition (Oxford University
Engineers, 1 edition (Prentice Hall,Oct 12, 1996) Press, Disember 16, 2009)
st
2. Robert L. Wood, C Programming for Scientists and Engineers
(Manufacturing Engineering Series) (Butterworth-Heinemann, Jun SMEB3201 SEMICONDUCTOR MATERIAL AND DEVICES
20, 2002) Charge Carriers in Semiconductors, Dopant Atoms and Energy
3. David R. Brooks, C Programming: The Essentials for Engineers Levels, The Extrinsic and Intrinsic Semiconductor, Fermi Energy Level,
and Scientists (Undergraduate Texts in Computer Science), 1 st Carrier Drift, Carrier Diffusion, The Hall Effect, Carrier Generation and
edition (Springer,Jun 4, 1999) Recombination, The pn Junction, pn Junction Diode, Metal-
Semiconductor and Semiconductor Heterojunctions,
SMEB2271 MATERIAL SCIENCE LABORATORY I Semiconductor devices: Bipolar Transistor, Field-Effect Transistor,
Students are attached to research labs carrying out mini-projects on Solar Cells, Photodetectors, Light Emitting Diodes, Tunnel Diode,
experiments in material science in characterizing electrical, optical, Microwave devices.
magnetic, mechanical, thermal properties of photonic materials, smart Semiconducting Materials Technology:
materials electrochemistry, polymer composite, semiconductor Materials used for photovoltaics cells: Crystalline Silicon, Cadmium
materials organic electronics , devices and advanced material telluride, Copper indium galium selenide, Gallium arsenide
processing while learning to use various characterizing equipment such multijunction, Light-absorbing dyes. Material engineering for high
as scanning electron microscopy, micro-Raman spectroscopy, UV-VIS- efficiency solar cells
NIR spectroscopy, Light microscopy, x-ray diffraction, scanning probe Light emitting diode: Material engineering for different colour of LED
microscopy , scanning electron microscopy, transmission electron and high efficiency white LED.
microscopy, auger electron spectroscopy, fast Fourier transform
infrared spectroscopy, four-point probe, thermogravimetry, differential Assessment Method:
scanning calorimetry, electrical impedance spectroscopy and simple Final Examination: 60%
material process technology. Students will be exposed with Labview Continuous Assessment: 40%
programming.
Medium of Instruction:
Assessment Method: English
Continuous Assessment: 100%
Soft-skills:
Medium of Instruction: CS3, CT3, LL2
English
References:
Soft-skills: 1. Semiconductor Material and Device Characterization by Dieter K.
CS2, CT3, LL2 Schroder (Jan 30, 2006)
2. Fundamentals of Semiconductors: Physics and Materials
References: Properties (Graduate Texts in Physics) [Hardcover] Peter Y. Yu
1. Y. Leng, Materials Characterization: Introduction to Microscopic (Author), Manuel Cardona (Author)
and Spectroscopic Methods, 1 edition (Wiley, Jun 2, 2008)
st
235

238 239 240 241 242 243 244 245 246 247 248