2. OBJECTIVE
The key objectives of this course will be to
-
Introduce different existing and emerging material for energy conversion, storage and consumption.
-
Builds a relationship between materials and energy in the context of a society’s consumption and its influence on the environment.
-
Introduce different scientific and technological background for energy generation and energy storage.
-
Discuss feasibility/cost of the most prominent sustainable energy conversion and storage methods.
-
Discuss challenges to achieve sustainable energy conversion and storage.
-
Introduce practical knowledge of synthesis of different photosensitive nanocrystal semiconductor.
-
Familiar with solution processed thin film solar cell fabrication and characterization.
3. COURSE CONTENT
UNIT-I : Energy resources & Consumption (2 Lectures)
Commercial and non-commercial forms of energy, worldwide scenario of energy resources and consumption.
UNIT-II: Energy generation and related material: (27 Lectures)
Solar cells:
Materials (2 lectures): Transparent conductor and semiconductor, active materials.
Fundamental of solar cell (7 lectures): Photophysics of active materials; exciton generation, carrier lifetime, and transport mechanism, solar spectrum and ideal solar cell, Quantum efficiency and power conversion efficiency.
Different class of solar cell (8 lectures): Si based, organic bulk heterojunction, CIGS-based, CdTe Thin Film Solar Cells, dye sensitized, perovskite-based, quantum dot based.
Fuel cell (4 lectures): Working principle of fuel cell, solid oxide fuel cell, polymer electrolyte membrane Fuel Cell, Phosphoric Acid Fuel Cell
H2 production from water (4 Lectures): Different technique for H2 generation, Electrolysis and photoelectrolysis technique, Photo catalytic technique, Thermochemical water splitting.
Wind energy (2 lectures): Basic concept about wind energy, Wind turbine and blade materials, new materials development, nanocomposite.
UNIT-III: Energy storage materials: (10 Lecture)
Different technique for energy storage, capacitor and batteries: materials for batteries, Li-batteries, metal hydride-batteries, electrode development, materials for hydrogen storage technology, supercapacitor, electrochemical double layer capacitor. Superconducting storage. Energy transmission materials, Energy management.
4. READINGS
4.1 TEXTBOOK:
-
Shashank Priya · Daniel J. Inman, “Energy Harvesting Technologies”, Springer
-
Jenny Nelson, “The Physics of Solar Cells”, Imperial College Press
-
Duncan W. Bruce, Dermot O'Hare, Richard I. Walton, “Energy Materials”, Wiley
4.2 REFERENCE BOOKS:
-
Vesselinka Petrova-Koch, Rudolf Hezel, adolf Goetzberger, “High efficiency low-cost photovoltaic”, Springer
-
Kathy Lu, “Materials in Energy Conversion, Harvesting”, and Storage, Wiley
5. OTHER SESSIONS
5.1 *TUTORIALS:: 0
5.2 *LABORATORY:: 5 Experiments
1. Synthesis of photosensitive Pb-based nanocrystal for thin film solar cell application.
2. Synthesis of photosensitive Cd-based nanocrystal for thin film solar cell application.
3. Fabrication of nanocrystal based solar cell in conventional structure.
4. Fabrication of nanocrystal based solar cell in inverted structure.
5. Characterization of thin film solar cell.
References:
1. Victor I Klimov “Nanocrystal quantum dot”- CRC Press,Taylor & Francis Group,
2. S. M. Sze, “Physics of semiconductor device” Wiley India Private Limited; Second edition
3. Jenny Nelson, “The Physics of Solar Cells” Imperial College Press
6. OUTCOME OF THE COURSE:
By the end of the course, students should be able to;
-
Differentiate between material and product lifecycles and be able to discuss these with relation to the environment
-
Explain limits and constraints to material selection for energy generation and storage and their effect on the environment
-
Rank common materials by production energy requirements and environmental impact.
-
Evaluate the influence social and personal choices have on energy and material use and evaluate the environmental impact of these choices
-
Interpret trends in energy and material use over time
-
Gain practical knowledge of nanocrystal semiconductor synthesis
-
Fabricate and characterize solution based thin film solar cell.
Semiconducting Materials
1. General
1.1 TITLE: Semiconducting Materials
1.2 COURSE NUMBER: DE.MS402.15
1.3 CREDITS: 3-0-2 - Credit 11
1.4 SEMESTER -OFFERED: Odd
1.5 Prerequisite: None
1.6 Syllabus Committee Member: Prof. D. Pandey, Prof. R. Prakash, Prof.P.Maiti, Dr.C.Rath, Dr.A.K.Singh, Dr.C.Upadhyay, Dr.B.N.Pal
2. OBJECTIVE
The general goal of this course is to allow the students to understand the fundamentals of semiconductor material and their behaviour. Emphasis will be given on the microscopic and macroscopic properties of semiconductors, relevant to their use as electronic materials. Course will also discuss about various conventional and emerging semiconductors. Different conventional semiconductor growth techniques will also be discussed. In addition, this course will introduces semiconductor device operation based on energy bands and carrier statistics. It will describe operation of p-n junctions, metal-semiconductor junctions and multi-junctions. Different solid state device application of semiconductors will be discussed including transistor, LED, Laser, solar cell, photodetector etc. In addition to theoretical knowledge, this course will introduce practical knowledge of synthesis of different types of semiconducting material by chemical method. Also, they will be familiar with different thin film device fabrication and characterization including field effect transistor and solar cell.
3. COURSE CONTENT
UNIT I: Characteristic Properties of Semiconductors (12 Lecture)
Energy-Band Structure, density of states and carrier concentration, Intrinsic and Extrinsic semiconductor, Doping and Defects in semiconductors, Carrier transport, Drift and diffusion current, Carrier mobility, Carrier generation and recombination, Photocurrent and light emission, Dimensionality and Quantum Confinement, Effects of Magnetic Fields
UNIT II: Examples of different commercial Semiconductors (5 Lecture)
Elemental Semiconductors and their alloys, Compound Semiconductors and Their Alloys
UNIT-III: Emerging semiconductors (5 Lecture)
Organic semiconductor, Metal oxide semiconductor, Quantum dot, Carbon nanotube, 2-D semiconductor.
UNIT IV: Growth techniques of different semiconductor (5 Lecture)
Czochralski Method, Bridgman Method, Chemical vapour deposition, Molecular beam epitaxy(MBE),
UNIT-V: Semiconductor junction (4 Lecture)
Metal-semiconductor junction, p-n junction, Semiconductor–heterostructure, Multijunction
UNIT-VI: Semiconductor devices (8 Lecture)
Transistor, Light emitting diode, Laser, Photovoltaic Solar Cells, Photodetector, Thermoelectric Devices
4. READINGS
4.1 TEXTBOOK:
1. S. M. Sze, Semiconductor device: Physics and technology, Wiley India Private Limited; Second edition
2. Donald Neamen, Dhrubes Biswas “Semiconductor Physics and Devices: Basic Principles”, McGraw Hill Education (India) Private Limited
3. Angus Rockett, Material science of semiconductors, Springer Science
4. Ben Streetman & Sanjay Banerjee, “Solid State Electronic Devices”, 6th edition, Prentice Hall (2005). ISBN: 978-0131497269.
4.2 REFERENCE BOOKS:
1. Betty Lise Anderson and Richard L. Anderson, “Fundamental of semiconductor devices”, TMH
2. Christos C Halkias, Jacob Millman, Satyabrata Jit, “Millman's Electronic Devices and Circuits”, Tata McGraw-Hill
3. D. N. Bose, “Semiconductor materials science and technology”, New Age International Pvt Ltd Publishers
5. OTHER SESSIONS
5.1 *TUTORIALS:: 0
5.2 *LABORATORY:: 6 Experiments
-
Synthesis of sol-gel material for metal oxide semiconductor.
-
Synthesis of colloidal quantum dot semiconductor.
-
Fabrication of metal oxide thin film transistor.
-
Fabrication of colloidal quantum dot solar cell.
-
Characterization of metal oxide thin film transistor.
-
Characterization of colloidal quantum dot solar cell.
References:
1. Victor I Klimov, “Nanocrystal quantum dot”- CRC Press, Taylor & Francis Group
2. S. M. Sze, “Physics of semiconductor device” Wiley India Private Limited; Second edition
3. Jenny Nelson, “The Physics of Solar Cells”, Imperial College Press
6. OUTCOME OF THE COURSE:
Upon successful completion of this course, students will be able to:
-
Understand the basic physical and electronic characteristics of crystalline semiconductor materials.
-
Understand the physical origins of electronic energy bands, lattice vibrational spectra, and other microscopic physical properties of semiconductors.
-
Understand the underlying microscopic physics behind the transport properties of semiconductors (electronic, magnetic, and thermal conduction and related properties).
-
Identify different conventional and emerging semiconductors.
-
Understand basic junction properties of semiconductors and their relation for solid state electronics application.
-
Be able to understand working principle of different semiconductor thin film devices and their application.
-
Gain practical knowledge of synthesis of different types of semiconducting materials.
-
Fabricate and characterize solution based thin film solar cell and transistor.
Optical Materials
1. General
1.1 TITLE: Optical Materials
1.2 COURSE NUMBER: DE.MS403.15
1.3 CREDITS: 3-0-0 - Credit 9
1.4 SEMESTER -OFFERED: Odd
1.5 Prerequisite: None
1.6 Syllabus Committee Member: Prof. D. Pandey, Prof. R. Prakash, Prof.P.Maiti, Dr.C.Rath, Dr.A.K.Singh, Dr.C.Upadhyay, Dr.B.N.Pal
2. OBJECTIVE
The main objective of this course is to give students a basic overview and understanding of different optical materials. The course will discuss about different microscopic properties of optical materials. It will also discuss about different phenomenon of semiconductor optics. In addition, the course will also discuss about the influence of light and electric field on different class of optical materials. Finally, a broad overview will be given on different application of optical materials.
3. COURSE CONTENT
Unit-1, Microscopic properties of optical materials: (9 Lectures)
Reflectance, transmittance, and absorption by the material. Optical constants, Dispersion equation, optical constants n and k, Fresnel equations, Scattering, polishing, surface roughness, Nonlinear polarization, Excitons, color centers, Polaritons.
Unit-2, Semiconductor Optics: (10 Lectures)
Optical properties of intrinsic excitons in bulk Semiconductors, Optical properties of bound and localized excitons and of defect states, Optical properties of excitons in structures of reduced dimensionality (nanostructure), Excitons Under the Influence of External Fields, From Cavity Polaritons to Photonic Crystals
Unit-3, Influence of light and electric field on different optical materials (10 Lectures)
Photoemission, Photogenerated electron-hole pair generation, Photo luminescence, Photo chromatic effect, Optical Polarizers, Faraday rotation, Electro luminescence, Electro chromatic effect, Electro-optical effect, Optical Polarizers, Faraday rotation.
Unit-4, Optical material for different application: (10 Lectures)
Photodetector, Light emitting diode, Laser, image sensor, Displays, Waveguide, Optical fibers
4. READINGS
4.1 TEXTBOOK:
-
Michael Bass, “Handbook of Optics (Vol. I and II)” McGraw Hill Publications
-
B Bhattacharya, “Semiconductor Opto-Electronics”, Pearson Education
-
Claus Klingshirn, “Semiconductor Optics”, Springer
-
HA Macleod, “Thin-Film Optical Filters” Adam Hilger Ltd.
4.2 REFERENCE BOOKS:
-
Gerd Keiser, “Optical Communication Essentials” Tata McGraw Hill(2008)
-
P.N. Prasad “Nanophotonics”, Wiley
-
J. Singh, “Optoelectronics: An introduction to materials and devices”, McGraw-Hill
5. OUTCOME OF THE COURSE:
Upon successful completion of this course, students will be able to:
-
Understand the basic knowledge of optical material and their application in various areas.
-
Understand the underlying microscopic physics behind the various optical properties of materials.
-
Be able to recognize the effect of light and electric filed on different optical materials.
-
Be able to understand working principle of different optical devices and their application. Able to predict material selection for different optical application by considering their physical properties.
|
Section-3AC2
|
Materials Science and Technology: 5-Year IDD VI-Semester
|
MC.CHI304.15
|
CHI304
|
Reaction Kinetics
|
3
|
0
|
3
|
12
|
DE.MS404.15
|
MS404
|
Advanced Ceramics (Pre req: Physical Behaviour of Materials & Crystallography & Crystal Structures) /(course from List DE2)
|
3
|
0
|
2
|
11
|
DE.MS406.15
|
MS406
|
Industrial Polymers/(course from List DE3)
|
3
|
0
|
0
|
9
|
OE.?????.15
|
?????
|
Open elective
|
3
|
0
|
0
|
9
|
IH/LM.H?0?.14
|
HU/LM???
|
Humanities/Language & Management Course
|
3
|
0
|
0
|
9
|
DP.MS391.15
|
MS391
|
UG Project
|
0
|
0
|
10
|
10
|
|
|
Total
|
15
|
0
|
15
|
60
|
GY.PE106.14
|
PE106
|
Sports/Creative Practice #
|
0
|
1
|
3
|
5
|
|
Reaction Kinetics
1. GENERAL
1.1 TITLE: Reaction Kinetics
1.2 *COURSE NUMBER (if known):: MC.CHI304.15
1.3 CREDITS: 3-0-3= (12 Credits)
1.4 SEMESTER-OFFERED: Even
1.5 PRE-REQUISITES: None
2. OBJECTIVE:
Basic concepts to those features of kinetics that seem to be important for understanding the rate processes. Course deals with the experimental and theoretical aspects of chemical reaction kinetics, including collision and transition-state theories, classical techniques, quantum and statistical mechanical estimation of rate constants, pressure-dependence and chemical activation. Reactions in the gas phase, liquid phase, and on surfaces are discussed with examples drawn from atmospheric, combustion, industrial, catalytic, and biological chemistry.
3. COURSE TOPICS:
Fundamental aspects of reaction kinetics, mechanism of complex reaction, rate equations for complex reaction non- stationary chain reaction with special reference to explosion reaction, kinetics and mechanism of ionic chain reactions (Polymerization reaction) and organic decomposition reaction.
(10 Lectures)
Potential energy surface and significance of energy of activation, collision and transition-state theories, classical techniques, quantum and statistical mechanical estimation of rate constants, uni-molecular reaction-Lindemann, Hinshelwood, RRK & RRKM treatment.
(09 lectures)
Theory of absolute reaction rate as applied to reaction in liquid state, ionic reactions, effect of salvation, ionic strength, and effect of solvent dielectric constant, secondary salt effect, Hammett equation.
(07 lectures)
Kinetics and mechanisms of homogeneous catalytic reactions, Arrheneous and van’t Hoff intermediates, acid – base catalysis, kinetics of enzymatic reaction- effect of pH and temperature.
(06 lectures)
Fast reactions- techniques for study of fast reactions. (03 lectures)
Kinetic treatment of diffusion in liquids and solids. (04 lectures)
4. READINGS
4.1 TEXTBOOK:
4.1.1 Chemical kinetics by K. J. Laidler
4.1.2 Fast reactions in solution by E.F. Caldin
4.1.3 Chemical kinetics and reaction dynamics by S. K. Upadhayay
4.1.4 Physical Chemistry by K.L. Papoor:
4.2 *REFERENCE BOOKS:
4.2.1 Kinetics and mechanism of chemical transformations by Rajaram and Kuroacose, Physical Chemistry by Atkins.
5. OTHER SESSIONS
5.1 *TUTORIALS: 0:
5.2 *LABORATORY: 1:
Experiments based on rates of reaction, activation energy and other aspects of kinetics.
5.3 *PROJECT: None:
6. ASSESSMENT (indicative only)
6.1 HA:: [xx% GRADE]
6.2 QUIZZES-HA: [10% GRADE]
6.3 PERIODICAL EXAMS: [30% GRADE]
6.4 *PROJECT: [xx% GRADE]
6.5 FINAL EXAM: [60% GRADE]
7. OUTCOME OF THE COURSE:
Basic understanding of the rate processes and theories relating to the rates of chemical reaction, Reactions in the gas phase, liquid phase, and on surfaces
List of Electives DE2
|
UG-CRC Code
|
Course Code
|
Course Name
|
L–T–P
|
Credits
|
DE.MS404.15
|
MS404
|
Advanced Ceramics (Pre req: Physical Behaviour & Crystallography & Crystal Structures)
|
3
|
0
|
2
|
11
|
DE.MS405.15
|
MS405
|
Science of Ceramics
|
3
|
0
|
0
|
9
|
|
|
|
|
|
|
|
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