Course ASL – 501
no:
Type of course Course Title Course Coordinator Course objectives: POs Semester
Open course (Y/N)
HM Course (Y/N)
DC (Y/N)
DE (Y/N)
Introduction to Smart Materials (Core)
Contact Hours
Autumn: Lecture 3
Tutorial
Spring Practical
0
0
Credits 3
Prerequisite course code as per proposed course numbers Prerequisite credits Equivalent course codes as per proposed course and old course Overlap course codes as per proposed course numbers Text Books: 1.
2.
Title Author Publisher Edition Title
3.
Author Publisher Edition Title
4.
Author Publisher Edition Title
5.
Author Publisher Edition Title Author Publisher Edition
Shape memory materials. Otsuka, Kazuhiro, and Clarence Marvin Wayman Cambridge university press, 1999 Smart materials and structures. Springer Science & Business Media. Gandhi M. V., & Thompson, B. D. (1992) Eds. Smart light-responsive materials: azobenzene-containing polymers and liquid crystals. Zhao, Yue, and Tomiki Ikeda John Wiley & Sons, 2009. Made to measure: New materials for the 21st century. , Ball, Philip Princeton University Press 1999. Smart materials and new technologies: for the architecture and design professions. Addington, D. Michelle, and Daniel L. Schodek Routledge, 2005
Reference Book: 1.
Title Author Publisher Edition 2. Title Author Publisher Edition Content Introduction: Basic concepts of smartness, Definition and characteristics. Smart Behaviours and Materials:. Classification: Piezoelectric, electrostrictive, magnetostrictive, pyroelectric, electrooptic, Piezomagnetism, Pyromagnetism, Piezoresitivity, Thermoelectricity, photon striction, shape memory alloy, Superelastic, Viscoelastic, Elastorestrictive, electrorheological, Thermochromic materials. Material properties and performance parameters: Phenomenology and constitutive relations. Material design and Engineering: Crystal structure, phase diagram, Effect of various parameter on material behavior. Smart composites: Introduction, working, application. Material Synthesis: Solid state reaction, sol-gel process. Measurement of properties: Testing and characterisation of materials. Applications: Design and fabrication of devices and structures and their integration with system: Biomorphs/Moonies, Chip capacitor, Memory devices (FRAM), Sensor, actuator and transducers, Accelerometer, Gyroscopes, Ultrasonic Motor, Liquid Crystal display, Photonics, Structural Health Monitoring. Course Continuous Evaluation 25% Assessment Mid Semester 25% End Semester 50%
Course ASL – 502
no:
Type of course Course Title Course Coordinator Course objectives:
Open course (Y/N)
HM Course (Y/N)
DC (Y/N)
DE (Y/N)
Shape Memory & Temperature Responsive Materials
POs Semester Contact Hours
Autumn: Lecture 3
Tutorial
Spring Practical
0
0
Credits 3
Prerequisite course code as per proposed course numbers Prerequisite credits Equivalent course codes as per proposed course and old course Overlap course codes as per proposed course numbers Text Books: 1.
2.
3.
4.
Title Author Publisher Edition Title Author Publisher Edition Title Author Publisher Edition Title Author
5.
Publisher Edition Title Author Publisher Edition
Shape memory materials. , Otsuka, Kazuhiro, and Clarence Marvin Wayman Cambridge university press 1999. Shape memory alloys: modeling and engineering applications. Lagoudas, Dimitris C., ed Springer Science & Business Media, 2008. Engineering aspects of shape memory alloys. Duerig, T. W., Melton, K. N., & Stöckel, D. Butterworth-Heinemann. (2013) Thin film shape memory alloys: fundamentals and device applications., Miyazaki, Shuichi, Yong Qing Fu, and Wei Min Huang, eds. Cambridge University Press 2009.
Reference Book: 1.
2.
Content
Course Assessment
Title Author Publisher Edition Title Author Publisher Edition Introduction to Temperature responsive polymers, History, Coil-globule transition, Phase diagrams of thermo-responsive polymers, thermodynamics of thermo-responsive polymers, Applications of temperature responsive polymer systems, bioseparation, thermoreposive surfaces – Tissue engineering, chromatography, Thermo-responsive gels, In situ-forming hydrogels Characterization of thermoresponsive polymer solutions, Cloud point, Hysteresis, Examples of thermoresponsive polymers, Thermoresponsivity in organic solvents, Thermoresponsivity in water. Applications of thermoresponsive polymers: nanocarriers for drug and gene delivery, smart textile applications. Polymer: Introduction to Shape Memory Polymers, Properties of shape-memory polymers, Triple-shape memory, Description of the thermally induced shape-memory effect, Thermodynamics of the shape-memory effect, Physically crosslinked SMPs, Linear block copolymers, Other thermoplastic polymers, Chemically crosslinked SMPs, Crosslinked polyurethane, PEO based crosslinked SMPs, Thermoplastic shape-memory Light-induced SMPs, Electro-active SMPs, Shape-memory polymers vs. shape-memory alloys, Applications - Industrial applications, Medical applications, Potential medical applications, Potential industrial applications, Brand protection and anti-counterfeitingAlloys: Introduction to Shape Memory Alloys, Overview and history, One-way vs. two-way shape memory, One-way memory effect, Two-way memory effect, Superelasticity, Crystal structures, Manufacture, Properties, Practical limitations- Response time and response symmetry, Structural fatigue and functional fatigue, Unintended actuation, Applications – Industrial, Aircraft and spacecraft, Automotive, Robotics, Civil Structures, Piping, Telecommunication, Medicine, Optometry, Orthopedic surgery, Dentistry, Engines, Crafts Continuous Evaluation 25% Mid Semester 25% End Semester 50%
Course no: Open course HM Course DC (Y/N) ASL – 503 (Y/N) (Y/N) Type of course Course Title Solid State Chemistry of Materials (Core) Course Coordinator Course objectives: POs Semester
Autumn: Lecture
Contact Hours
3
Tutorial
Spring Practical
0
0
DE (Y/N)
Credits 3
Prerequisite course code as per proposed course numbers Prerequisite credits Equivalent course codes as per proposed course and old course Overlap course codes as per proposed course numbers Text Books: 1.
2.
3.
4.
5.
Title
Concept and Models of Inorganic Chemistry
Author Publisher Edition Title Author Publisher Edition Title Author
B. E. Douglas, D. H. McDenial, and J. J. Alexander, John Wiley & Sons (3rd ed.), (2001). Solid State Chemistry: An Introduction, L. Smart and E. Moore, Nelson Thornes Ltd. (2001). Advanced inorganic Chemistry. F. A. Cotton, G. Wilkinson, C. A. Murillo and M. Bochann John Wiley & Sons (6th ed.), , (1999) New Directions in Solid State Chemistry,
Publisher Edition Title Author Publisher Edition Title Author Publisher Edition
C. N. R. Rao and J. Gopalakrishnan, Cambrige University Press (1997)
Reference Book: 1.
2.
Content
Course Assessment
Title Author Publisher Edition Title Author Publisher Edition Solid-State of Materials: Crystalline solid, overview of close packing, packing efficiency, cubic, octahedral and tetrahedral interstitial site, limiting radius ratio, method of determination of ionic radii Ionic Crystal Containing Two Different Elements: Cesium Chloride, rook-salt, Zinc blende, wurtzite, fluorite, antifluorite, nickel-arsenide, CaC2, CdI2 and rutile structures Ionic Crystal Containing 3 Different Elements: Ilmenite, spinels, inverse spinels, granets, perovskite and KNiF3 Non-Ionic Crystal: Giant molecules, layer structure, crystal composed of discreet molecules. Synthesis of Materials and Defects: Hydrothermal, sol-gel, co-precipitation (precursor), ceramic method, Different methods to grow single crystal. Defect Solid State Structures: Schottky and Frenkel defects, solid electrolytes, non-stoichiometric compound, F-centers and other defects in non-stoichiometric compounds. Amorphous and Mesoporous Materials Amorphous Inorganic Material: Glasses, refractories, materials obtained from organometallic chemical vapour deposition (OCVD). Mesoporous Materials: Various type of mesoporous martials (oxides sulphides, etc) tailoring of pore sized, application of mesoporous materials in heterogeneous catalysis. New Materials: Conducting polymers, carbon nanotubes, carbon nanorods and fullerenes. Electronic Materials, Insulating semiconducting superconducting materials, ferroelectrics, dielectrics Continuous Evaluation 25% Mid Semester 25% End Semester 50%
Course no: Open course HM Course ASL – 504 (Y/N) (Y/N) Type of course Course Title Environment & Smart Materials (Core) Course Coordinator Course objectives: POs Semester Contact Hours
Autumn: Lecture 3
DC (Y/N)
Tutorial
Spring Practical
0
0
DE (Y/N)
Credits 3
Prerequisite course code as per proposed course numbers Prerequisite credits Equivalent course codes as per proposed course and old course Overlap course codes as per proposed course numbers Text Books: 1.
4.
Title Author Publisher Edition Title Author Publisher Edition Title Author Publisher Edition Title
Principles and Prevention of Corrosion, D. A. Jones Macmillan (1996). The Fundamental of Corrosion C. Scully Pergamon Press (2nd ed.),, (2000). Corrosion Engineering (3rd ed.), M.G. Fontana, McGraw Hill (1986). Electrodeposition and Corrosion Control, ,
5.
Author Publisher Edition Title
J. M. West Wiley (2000). Corrosion Handbook Series), , Edited by W. Revie John Wiley and Sons
2.
3.
Author Publisher
(Electrochemical
Society
Edition Reference Book: 1.
2.
Content
(2000).
Title Author Publisher Edition Title Author Publisher Edition Environmental implications: Environmental effects from the chemical processes industry (like Pulp mill operations, bleach plants, boilers, paper machine, water treatment plants in the pulp and paper industry and others), infrastructure, and transportation industry Corrosion:
Basics
of
Corrosion,
Different
forms
of
Corrosion,
electrochemical corrosion, thermodynamic principles of electrochemical reactions, Electromotive Force Series, Pourbaix Diagrams, Evans Diagrams, Mixed Potential Theory, Passivity Measurement of
Corrosion:
Electrochemical
methods
to Measure
Corrosion: DC Polarization, AC Impedance, Environmentally Induced Cracking, Corrosion Fatigue, Hydrogen Induced Cracking, Application of Fracture mechanics Effects and Prevention of Corrosion: Atmospheric Corrosion, Oxidation in Gaseous Environments, Ellingham Diagrams, Role of Protective Scale, Molten Salt Corrosion, Environmental degradation of ceramics, Degradation of Polymeric Materials, Microbial corrosion, Corrosion of Bio-Implants, Corrosion Prevention methods Course Assessment
Continuous Evaluation 25% Mid Semester 25% End Semester 50%
Course no: Open course HM Course DC (Y/N) ASL – 505 (Y/N) (Y/N) Type of course Course Title Modelling & Fabrication of Smart Materials (Mandatory) Course Coordinator Course objectives: POs Semester Contact Hours
Autumn: Lecture 3
Tutorial
Spring Practical
0
0
DE (Y/N)
Credits 3
Prerequisite course code as per proposed course numbers Prerequisite credits Equivalent course codes as per proposed course and old course Overlap course codes as per proposed course numbers Text Books: 1.
2.
3.
4.
Title Author Publisher Edition Title Author Publisher Edition Title Author Publisher Edition Title Author
5.
Publisher Edition Title Author Publisher Edition
Shape memory materials. , Otsuka, Kazuhiro, and Clarence Marvin Wayman. Cambridge university press 1999. Shape memory alloys: modeling and engineering applications. , Lagoudas, Dimitris C., ed. Springer Science & Business Media 2008. Engineering aspects of shape memory alloys. . Duerig, T. W., Melton, K. N., & Stöckel, D. Butterworth-Heinemann (2013). Thin film shape memory alloys: fundamentals and device applications, . Miyazaki, Shuichi, Yong Qing Fu, and Wei Min Huang, eds Cambridge University Press 2009
Reference Book: 1.
2.
Content
Course Assessment
Title Author Publisher Edition Title Author Publisher Edition Modeling of Smart Materials: Introduction, basic concepts, classifications, applications. Modeling of Piezoelectric Materials: Fundamental equations of piezoelectricity, Piezoelectric Property, Crystal Structure Crystal Structure, Constitutive Relationship, Active Strain Evaluation, Simplified Equation for Simplified Equation for Piezo –patch, Active Strain Expression, Piezoelectric Coefficients, A Comparison of Properties A Comparison of Properties. Modeling of Strain Induced Actuation: Constitutive Relationship of Piezoelectric Material, Simplified Equations for Piezo-patch, Piezoelectric Constants, Different Piezoelectric Materials an d their properties, Piezo-actuators, displacement and force measurement techniques, Induced Strain Actuation (ISA) – Uniform Strain Model, Static Equilibrium Configuration against Uniform Strain Uniform Strain, Configuration against Bending Strain, ISA – Euler-Bernoulli Model • ISA Model for Magnetostrictive Mini ISA Model for Magnetostrictive Mini Actuator , Active Fibre Composite Actuation Fabrication of Smart Materials: Smart polymers, smart ceramics, smart metals & alloys, fibre-reinforced composite manufacturing technologies, plastic product manufacturing technologies. Continuous Evaluation 25% Mid Semester 25% End Semester 50%
Course no: Open course HM Course DC (Y/N) ASL – 506 (Y/N) (Y/N) Type of course Course Title Material Characterization Techniques (Mandatory) Course Coordinator Course objectives: POs Semester Contact Hours
Autumn: Lecture 3
Tutorial
Spring Practical
0
0
DE (Y/N)
Credits 3
Prerequisite course code as per proposed course numbers Prerequisite credits Equivalent course codes as per proposed course and old course Overlap course codes as per proposed course numbers Text Books: 1.
2.
3.
4.
Title Author Publisher Edition Title Author Publisher Edition Title Author Publisher Edition Title Author
5.
Publisher Edition Title Author Publisher Edition
Materials Characterisation Techniques, , S. Zhang, L. Li and A. Kumar CRC Press (2009) Microstructural Characterization of Materials, D. Brandon and W.D. Kaplan, John Wiley and Sons (2008) Science of Microscopy, P.W. Hawkes and J.C.H. Spence, Springer (2007) Scanning Electron Microscopy & X-Ray Microanalysis, J. Goldstein, D. E. Newbury, D. C. Roy, C. E. Lyman, P. Echlin, E. Lifshin, L. Sawyer, and J. R. MichaeL Springer (2003)
Reference Book: 1.
2.
Content
Course Assessment
Title Author Publisher Edition Title Author Publisher Edition Diffraction and Imaging: Fundamentals of diffraction Interaction of matter with electromagnetic signal and the resultant response X-ray diffraction (XRD), Bragg’s formula, powder diffraction, Laue method, crystallography Scherer formula, strain and gain size determination Imaging: basics, performance parameters (resolution, magnification, depth of focus/field) Aberrations: spherical and chromatics, astigmatism, distortion Imaging Techniques Optical microscopy: Fundamentals, quantitative analysis, applications Scanning electron microscopy (SEM): basics, modes, image contrast, applications Transmission electron microscopy (TEM): basic mechanism, theory of diffraction contrast in TEM, image analysis, application in analyzing the crystal defect analysis Techniques/methods for interpretation of analytical data Scanning Tunneling Microscope (STM) Atomic Force Microscope (AFM) and Nano indentation Thermal Analysis: Differential thermal analyzer (DTA), Thermogravimetric analysis (TGA) Differential Scanning Calorimetry (DSC), dilatometry Spectroscopy techniques: Basic concept of spectroscopy-based analysis Wavelength-dispersive Spectroscopy (WDS), Energy-dispersive Spectroscopy (EDS), role of X-rays Electron probe micro-analyzer (EPMA) and applications, Auger electron spectroscopy X-ray photon spectroscopy, Secondary ion mass spectroscopy (SIMS), Electron energy loss spectroscopy (EELS) Vibrational spectroscopy (IR and Raman), UV-visible spectroscopy, Chemical Analysis and other techniques: Nuclear Magnetic Resonance (NMR), Electron spin resonance (ESR) Continuous Evaluation 25% Mid Semester 25% End Semester 50%
Course no: Open course HM Course ASL – 517 (Y/N) (Y/N) Type of course Course Title Smart Biomedical Materials Course Coordinator Course objectives: POs Semester
Autumn: Lecture
Contact Hours
3
DC (Y/N)
Tutorial
Spring Practical
0
0
DE (Y/N)
Credits 3
Prerequisite course code as per proposed course numbers Prerequisite credits Equivalent course codes as per proposed course and old course Overlap course codes as per proposed course numbers Text Books: 1.
Title
3.
Author Publisher Edition Title Author Publisher Edition Title
4.
Author Publisher Edition Title
2.
5.
Reference Book: 1.
Author Publisher Edition Title Author Publisher Edition Title Author
Titanium in medicine: material science, surface science, engineering, biological responses and medical applications. Brunette, Donald Maxwell, et al., eds Springer Science & Business Media, 2012. Collagen: structure and mechanics, an introduction Fratzl Springer US. P. (2008). (pp. 1-13). The language of shape: the role of curvature in condensed matter: physics, chemistry and biology. Hyde, Stephen, et al. Elsevier, 1996. Optimization of structural topology, shape, and material. Bendsoe, Martin P. Berlin etc: Springer Vol. 2. , 1995 Bio-applications of Nanoparticles. Chan, Warren CW, ed. Springer Science & Business Media Vol. 620. , 2009.
2.
Publisher Edition Title Author Publisher Edition
Content
Course Assessment
Continuous Evaluation 25% Mid Semester 25% End Semester 50%
Course no: Open course HM Course ASL – 519 (Y/N) (Y/N) Type of course Course Title Smart Materials & Devices Course Coordinator Course objectives: POs Semester Contact Hours
Autumn: Lecture 3
DC (Y/N)
Tutorial
Spring Practical
0
0
DE (Y/N)
Credits 3
Prerequisite course code as per proposed course numbers Prerequisite credits Equivalent course codes as per proposed course and old course Overlap course codes as per proposed course numbers Text Books: 1.
2.
3.
4.
5.
Title Author Publisher Edition Title Author Publisher Edition Title Author Publisher Edition Title
Author Publisher Edition Title Author Publisher Edition
Shape memory materials Otsuka, Kazuhiro, and Clarence Marvin Wayman. Cambridge university press 1999. Shape memory alloys: modeling and engineering applications. Lagoudas, Dimitris C., ed. Springer Science & Business Media 2008. Engineering aspects of shape memory alloys. Duerig, T. W., Melton, K. N., & Stöckel, D. Butterworth-Heinemann. (2013) eds. Thin film shape memory alloys: fundamentals and device applications. Miyazaki, Shuichi, Yong Qing Fu, and Wei Min Huang Cambridge University Press 2009.
Reference Book: 1.
Title Author Publisher Edition Title Author Publisher Edition
2.
Content Unit I Smart Materials and Devices – Instrumented structures functions and response, Sensing systems, Self-diagnosis, Signal processing consideration, Actuation systems and effectors Unit II Strain Measuring Techniques using Electrical strain gauges, Types, Resistance,
Capacitance,
Inductance,
Wheatstone
bridges,
Pressure
transducers, Load cells, Temperature Compensation, Strain Rosettes. Sensing Technology, Types of Sensors, Physical Measurement using Piezo Electric Strain measurement, Inductively Read Transducers, The LVOT, Fiber optic Techniques. Chemical and Bio-Chemical sensing in structural Assessment, Absorptive chemical sensors, Spectroscopes, Fibre Optic Chemical Sensing Systems and Distributed measurement. Actuator Techniques, Actuator and actuator materials, Piezoelectric and Electrostrictive Material, Magnetostructure Material, Shape Memory Alloys, Electro rheological Fluids–Electro magnetic actuation, Role of actuators and Actuator Materials. Data Acquisition and Processing – Signal Processing and Control for Smart Structures, Sensors as Geometrical Processors, Signal Processing, Control System – Linear and Non-Linear. Course Assessment
Continuous Evaluation 25% Mid Semester 25% End Semester 50%
Course no: Open course HM Course ASL – 512 (Y/N) (Y/N) Type of course Course Title Manufacturing of Plastic Products Course Coordinator Course objectives: POs Semester
Autumn: Lecture
Contact Hours
DC (Y/N)
Tutorial
Spring Practical
0
0
3
DE (Y/N)
Credits 3
Prerequisite course code as per proposed course numbers Prerequisite credits Equivalent course codes as per proposed course and old course Overlap course codes as per proposed course numbers Text Books: 1.
Title
Flow of High Polymers, S. Middleman, Interscience Publishers 1968.
2.
Author Publisher Edition Title Author Publisher Edition
J. F. Gerard, Wiley-VCH verlag GmbH,
Title Author Publisher Edition Title
Understanding Injection Molding Technology by , , Herbert Rees Hanser Publishers 1994.
Author Publisher Edition
Marcel Dekker Inc
3.
4.
Fillers and Filled Polymers,
2001.
Handbook of polymer Testing Roger Brown, ,
1999
5.
Reference Book: 1.
2.
Content
Title Author Publisher Edition Title Author Publisher Edition Title Author Publisher Edition Introduction to Polymers & Plastics -Types of polymers, Commodity plastics and special purpose plastics, Environment friendly plastics, Plastic recycling & plastic identification codes, Additives and fillers Polymer processing technologies - Melt flow, Extrusion, Injection molding, Rotational molding, Compression molding, Polymer foaming, Vacuum forming, Filament winding, Thermoforming, Calendaring, Resin transfer molding Fiber Reinforced Polymeric Composites - Introduction, Types of fibers, Manufacturing techniques, Micro & Macro mechanical analysis of Lamina, Testing of composites, fiber volume fraction, tensile, shear, compressive, flexural and thermoelastic responses of lamina and laminates, shear test, notched strength, essential work of fracture, fracture toughness, non destructive testing. Testing of polymer products - Testing of plastics and dry rubber products – mechanical properties – tensile, Flexural, compressive, impact, hardness, abrasion and fatigue resistance tests, Thermal properties – thermal conductivity, thermal expansion and brittleness temperature, heat deflection temperature, Types of material characterization techniques, MFI, capillary rheometer test, viscosity, gel time and peak exothermic temperature. Manufacturing of test specimens Selecting plastics for end-applications
Course Assessment
Automotive applications, Aerospace applications, House-hold applications, Textile applications, Food & packaging applications Continuous Evaluation 25% Mid Semester 25% End Semester 50%
Course no: Open course HM Course ASL –511 (Y/N) (Y/N) Type of course Course Title Active Smart Polymers Course Coordinator Course objectives: POs Semester
Autumn: Lecture
Contact Hours
DC (Y/N)
Tutorial
Spring Practical
0
0
3
DE (Y/N)
Credits 3
Prerequisite course code as per proposed course numbers Prerequisite credits Equivalent course codes as per proposed course and old course Overlap course codes as per proposed course numbers Text Books: 1.
Title
Smart
light-responsive
materials:
azobenzene-containing polymers and liquid crystals.
2.
Author Publisher Edition Title
3.
Author Publisher Edition Title Author Publisher
4.
Edition Title Author Publisher Edition
Zhao, Yue, and Tomiki Ikeda, eds. John Wiley & Sons 2009 Smart polymers: applications in biotechnology and biomedicine. , Galaev, Igor, and Bo Mattiasson, eds CRC Press 2007. "Smart polymers: physical forms and bioengineering applications." Progress in Polymer Science Kumar, Ashok, et al
32.10 (2007): 1205-1237 Smart fibres, fabrics and clothing: fundamentals and applications. ao, X. M., ed Elsevier, 2001.
5.
Reference Book: 1.
2.
Title Author Publisher Edition
Functional coatings: by polymer microencapsulation. , Ghosh, Swapan Kumar. John Wiley & Sons 2006.
Title Author Publisher Edition Title Author Publisher Edition
Content
Course Assessment
Continuous Evaluation 25% Mid Semester 25% End Semester 50%
Course no: Open course HM Course DC (Y/N) ASL – 513 (Y/N) (Y/N) Type of course Course Title Materials for Renewable Energy and Storage Course Coordinator Course objectives: POs Semester
Autumn: Lecture
Contact Hours
Tutorial
Spring Practical
0
0
3
DE (Y/N)
Credits 3
Prerequisite course code as per proposed course numbers Prerequisite credits Equivalent course codes as per proposed course and old course Overlap course codes as per proposed course numbers Text Books: 1.
Title
Hand book of fuel cells: advances in electro catalysis materials, diagnostics and durability, .
2.
Author Publisher Edition Title Author Publisher Edition
3.
Title
W. Vielstich, Wiley (2009) Solar Collectors, Energy Storage, and Materials (Solar Heat Technologies), F. Winter, MIT Press USA (1991) Fundamentals
of
Materials
Environmental Sustainability,
4.
Author Publisher Edition Title Author Publisher Edition
D. S. Ginley and D. Cahen, Cambridge University Press (2011)
for
Energy
and
5.
Reference Book: 1.
2.
Content
Course Assessment
Title Author Publisher Edition Title Author Publisher Edition Title Author Publisher Edition Introduction and Fundamental Concepts: Introduction to new generation of materials and nano-engineering of their structures for sustainable energy economy Contribution to high performance renewable energy production, storage, conversion and usage. Solar grade glass; (a) properties-transparency, emissivity and reflectivity, and (b) manufacturing-Flat glass for PV & CSP, tube glass for Evacuated Tube Receiver (ETR) and Collector (ETC). Solar Cells Solar Photo Voltaic (PV) cells: Single and multi-crystalline silicon solar cells Amorphous silicon, thin film; Cd-Te, CIGS, CZTS, nano-, micro-, poly-Si Transparent conducting coating, Multi-junction, solar PV concentrator, flexible solar cells, Emerging PV; dye sensitized, other organic, and quantum dot cells Nano-engineered materials. Concentrated Solar Power Materials: Materials for Concentrated Solar Power (CSP) Reflector materials: glass, metal, polymer and film Receiver and collectors, absorptive coating and anti-reflective coating Materials and shapes for thermal storage Lithium ion Batteries. Fuel Cells Fuel cells: materials and construction PEM Fuel Cell (FC), AFC, PAFC, MCFC, SOFC Catalysts for electro catalysis Fuel reformer and water splitting. Continuous Evaluation 25% Mid Semester 25% End Semester 50%
Course no: Open course HM Course ASL – 514 (Y/N) (Y/N) Type of course Course Title Spectroscopic Techniques for Materials Course Coordinator Course objectives: POs Semester
Autumn: Lecture
Contact Hours
DC (Y/N)
Tutorial
Spring Practical
0
0
3
DE (Y/N)
Credits 3
Prerequisite course code as per proposed course numbers Prerequisite credits Equivalent course codes as per proposed course and old course Overlap course codes as per proposed course numbers Text Books: 1.
Title
Transmission electron microscopy: A Text Book of Materials Science,
2.
Author Publisher Edition Title Author Publisher Edition
D. B. Williams and C. B. Carter, Springer (2009). Instrumental Methods of Chemical Analysis (5th ed.), , G. W. Ewing Mcgraw-Hill College
3.
Title
4.
Author Publisher Edition Title
Infrared and Raman Spectra of Inorganic and Coordination Compounds (5th ed.), , K. Nakamoto John Wiley & Sons (1997).
Author Publisher Edition
(1985)
Basic concept of analytical chemistry, S. M. Khopkar, New Age International (2008).
5.
Title Author Publisher Edition
Reference Book: 1.
Title Author Publisher Edition Title Author Publisher Edition
2.
Content
Fundamental Molecular Spectroscopy C. N Banwell and E. M McCash, McGraw Hill Education India (5th ed.), (1995).
UV-Visible & Raman Spectroscopy: Electromagnetic Radiation Spectrum, UV-Visible Spectroscopy of Materials FTIR Spectroscopy, Theory of Raman Spectroscopy Instrumentation, Sample Handling and Illumination Diagnostic Structural Analysis Polarization Measurements, Quantitative Analysis-Micro Raman Nuclear Magnetic Resonance (NMR) Spectroscopy: Basic Principles of NMR Spectroscopy, Continuous Wave NMR Spectrometers Pulsed Fourier Transform NMR Spectrometer, Spectra & Molecular Structure Quantitative Analysis Electron Spin Resonance (ESR) Spectroscopy: Electron Behavior, ESR Spectrometer ESR Spectra, Interpretation of ESR Spectra Quantitative Analysis Mass Spectrometry: Ion Scattering Spectrometry (ISS) Secondary Ion Mass Spectrometry (SIMS) Auger Emission Spectroscopy (AES) Electron Spectroscopy for Chemical Analysis (ESCA) Low Energy Electron Diffraction (LEED) Photoelectron Spectroscopy (PES)
Course Assessment
Continuous Evaluation 25% Mid Semester 25% End Semester 50%
Course no: Open course ASL –515 (Y/N) Type of course Course Title Smart Ceramics Course Coordinator Course objectives: POs Semester Contact Hours
Autumn: Lecture 3
HM Course (Y/N)
DC (Y/N)
Tutorial
Spring Practical
0
0
DE (Y/N)
Credits 3
Prerequisite course code as per proposed course numbers Prerequisite credits Equivalent course codes as per proposed course and old course Overlap course codes as per proposed course numbers Text Books: 1.
3.
Title Author Publisher Edition Title Author Publisher Edition Title
4.
Author Publisher Edition Title
2.
5.
Author Publisher Edition Title Author Publisher Edition
"Oxide ceramics." Ryshkewitch, Eugene, and David W. Richerson (1985) Shape memory materials., Otsuka, Kazuhiro, and Clarence Marvin Wayman Cambridge university press 1999. Handbook of properties of technical and engineering ceramics., Morrell, Roger Hmso 1987 "Sintering theory and practice." Solar-Terrestrial Physics (Solnechno-zemnaya fizika) Randall M. German, (1996): 568
Reference Book: 1.
2.
Content
Course Assessment
Title Author Publisher Edition Title Author Publisher Edition Introduction: Definition & scope of ceramics and ceramic materials. Examples of ceramic crystals, short- range and long-range order, imperfections, polymorphism Ceramic Binary and ternary systems, ceramic microstructures. Crystallization of glass and glass-ceramics Thermal, electrical, magnetic and optical properties of ceramics and application Classification of ceramic materials conventional and advanced, Areas of applications Ceramics: Conventional ceramics, refractories, classification of refractories, modern trends and developments, basic raw materials Elementary idea of manufacturing process technology, flow diagram of steps necessary for manufacturing, basic properties and areas of application Whitewares: classification and types, elementary idea of manufacturing process technology including body preparation, basic properties and application areas Ceramic coatings: types of glazes and enamels, elementary ideas on compositions, process of enamelling & glazing and their properties. Glass, definition of glass, basic concepts of glass structure, batch materials and minor ingredients and their functions, elementary concept of glass manufacturing process, different types of glasses, application of glasses Cement & Concrete: concept of hydraulic materials, basic raw materials, manufacturing process, basic compositions of OPC. compound formation, setting and hardening. tests of cement and concrete. Fabrication methods and materials: Elementary ideas about the raw materials used in pottery, heavy clayweres, raw materials clays and their classification Quartz, polymorphism of quartz, feldspar and its classification, Talc, Steatite and Mica Fabrication methods: packing of powders, classification and scope of various fabrication methods Dry and semi dry pressing. extrusion, Jiggering & jollying, slip casting HP & HIP Drying & firing of ceramics: Biscuit firing and glost firing, fast firing technology, action of heat on triaxial body, elementary ideas of various furnaces used is ceramic industries Advanced Ceramics: Advanced ceramics, bio-ceramics, space ceramics, automotive ceramics, electronic ceramics Superconducting ceramics, elementary ideas of their preparation and applications. Continuous Evaluation 25% Mid Semester 25% End Semester 50%
Course no: Open course HM Course ASL –516 (Y/N) (Y/N) Type of course Course Title Computer Aided Product Design Course Coordinator Course objectives: POs Semester
Autumn: Lecture
Contact Hours
DC (Y/N)
Tutorial
Spring Practical
0
0
3
DE (Y/N)
Credits 3
Prerequisite course code as per proposed course numbers Prerequisite credits Equivalent course codes as per proposed course and old course Overlap course codes as per proposed course numbers Text Books: 1.
Title
Direct-write technologies for rapid prototyping applications: sensors, electronics, and integrated power sources.,
2.
Author Publisher Edition Title Author Publisher Edition
Piqué, Alberto, and Douglas B. Chrisey, eds Academic press 2001. Principles of cad/cam/cae systems. ., Lee, Kunwoo. Addison-Wesley Longman Publishing Co., Inc
3.
Title
Rapid prototyping: principles and applications. Chua, Chee Kai, and Kah Fai Leong. World Scientific, Vol. 1. 2003.
4.
Author Publisher Edition Title Author Publisher Edition
Wood, Lamont. Industrial Press, Inc. , 1993.
1999.
Rapid automated prototyping.
5.
Title
Rapid
manufacturing:
the
technologies
and
applications of rapid prototyping and rapid tooling. . Author Publisher Edition Reference Book: 1.
2.
Content
Pham, Duc, and Stefan S. Dimov. Springer Science & Business Media, 2012
Title Author Publisher Edition Title Author Publisher Edition Introduction: Significance of product design, product design and development process, sequential engineering design method, the challenges of product development, World Class manufacturing, Product definition, Engineering Design Process, Prototype Design and Innovation, Impact of Cost, Quality and time, Key Process Requirements for Rapid Prototyping Prototyping: Product Prototyping, Prototype planning and management, Prototype cost estimation, Prototype Design Methods and tools. Materials Selection and Product Prototyping. Phases of Prototyping. Fundamentals of R.P. Classification of R.P. Processes. Concept Generation: Activities of concept generation, clarifying problem, search both internally and externally, explore the output, Concept Testing: Elements of testing: qualitative and quantitative methods including survey, measurement of customers’ response Rapid Prototyping Process: - Automated Processes, Difference between Additive and Subtractive Processes, Process Chain, steps in involved in R.P. Types of R.P. systems: - Liquid Based, Solid Based, & Powder Based. Application of R.P. in Manufacturing and Rapid Tooling: Rapid Prototyping and Manufacturing Benchmarking. Modeling practice on softwares such as IDEAS, UNIGRAPHICS, ProE, etc
Course Assessment
Continuous Evaluation 25% Mid Semester 25% End Semester 50%
Course no: Open course HM Course ASL – 518 (Y/N) (Y/N) Type of course Course Title Computational Material Science Course Coordinator Course objectives: POs Semester
Autumn: Lecture
Contact Hours
DC (Y/N)
Tutorial
Spring Practical
0
0
3
DE (Y/N)
Credits 3
Prerequisite course code as per proposed course numbers Prerequisite credits Equivalent course codes as per proposed course and old course Overlap course codes as per proposed course numbers Text Books: 1.
Title
Computational fluid dynamics. , Roache, Patrick J. Hermosa publishers 1972
2.
Author Publisher Edition Title Author Publisher Edition
Nalwa, Hari Singh, and Seizo Miyata CRC press
Title Author Publisher Edition Title
Computational thermodynamics: the Calphad method. Lukas, Hans Leo, Suzana G. Fries, and Bo Sundman. Cambridge: Cambridge university press Vol. 131. , 2007
3.
4.
. Nonlinear optics of organic molecules and polymers. ,
1996.
Computational materials science: from ab initio to Monte Carlo methods
Author Publisher Edition
Ohno, Kaoru, Keivan Esfarjani, and Yoshiyuki Kawazoe Springer Science & Business Media . Vol. 129. , 2012.
5.
Reference Book: 1.
2.
Content
Title
The coming of materials science., .
Author Publisher Edition
Cahn, Robert W. New York 2001
Title Author Publisher Edition Title Author Publisher Edition Introduction - Introduction to various regimes, multiscale modelling & simulation of materials, System size vs computation time, Parallel processing Atomistic Level Modelling: Review of thermodynamic laws, micro & macro state, ergodic system, partition function, statistical mechanics, thermodynamic ensembles, Monte Carlo simulation- Markov process, algorithm and application of MC simulation (percolation problem etc). molecular dynamicsforce fields, MD algorithm, accelerating MD, verlet algo, leap frog method, velocity verlet method, gear algo, particle mesh method, multipole method, fast multipole method. Lattice Mesoscale methods: Lattice gas automata, lattice director model. Ab Initio Methods: Density functional theory, quantum mechanics, schrodinger wave equation, many particle system, car parrinello method, born openheimer
approximation,
hohenberg-kohn
theorem,
kohn
sham
formulation, local density approximation, bloch’s theorem, pseudo potential, energy minimisation techniques, examples of crystals and non-crystals. Coarse graining: Particle based models-Lattice gas model, connolly williams approximation, spatial models, dynamic (temporal) models, application to polymer and polar materials. grain continuum modelling, computational micro-mechanics, multiscale coupling
Course Assessment
Continuous Evaluation 25% Mid Semester 25% End Semester 50%
Course no: Open course HM Course ASL –520 (Y/N) (Y/N) Type of course Course Title Smart Porous Materials Course Coordinator Course objectives: POs Semester
Autumn: Lecture
Contact Hours
DC (Y/N)
Tutorial
Spring Practical
0
0
3
DE (Y/N)
Credits 3
Prerequisite course code as per proposed course numbers Prerequisite credits Equivalent course codes as per proposed course and old course Overlap course codes as per proposed course numbers Text Books: 1.
Title
Metal Organic Catalysts,
2.
Author Publisher Edition Title Author Publisher Edition
J. Gascon, RSC (2013). Introduction to Metal−Organic Frameworks, O. M. Yaghi, ACS
Title
Metal-Organic
3.
Frameworks
as
(2012) Frameworks:
Applications
Catalysis to Gas Storage
4.
Heterogeneous
Author Publisher Edition Title
D. Farrusseng, ,John Wiley & Sons (2011).
Author Publisher Edition
D. W. Bruce, D. Hare, and R. I. Walton John Wiley and Sons (2011).
Porous Materials, ,
from
5.
Reference Book: 1.
2.
Content
Title Author Publisher Edition Title Author Publisher Edition Title Author Publisher Edition Introduction to Porous Materials: Porous materials including polymer networks, zeolites, mesoporous silicas, covalent organic frameworks (COFs) and porous metal organic frameworks (MOFs) Importance of porous materials and their classification using BET and Langmuir models of surface area and pore size Synthesis and properties porous materials: Synthesis of zeolites and mesoporous silicas, including templating strategies Historical development and synthesis of metal-organic frameworks (MOFs) and their relationship to zeolites and porous silicas in terms of structure and stability Deferent types of organic-ligands used in MOFs synthesis Isoreticular synthesis and metallo-ligand approach for MOFs synthesis Rational approach towards topology and function, post-modification strategies Structural analysis of porous materials: Structural analysis of porous material using different techniques, X-ray powder diffraction (i.e., of microcrystals) Single crystal X-ray analysis, scanning electron microscopy (SEM) and energy dispersive X-ray spectroscopy (EDS), transmission electron microscopy (TEM) Thermal analysis and various spectroscopic methods of analysis. Network structures and topological analysis, theoretical description, simulation and modeling of MOFs. Gas adsorption, surface area, pore volume analysis and sample preparation Application of porous materials: Applications of porous material in storage and separation of strategically important gases (H2, CO2, CH4), drug delivery and catalytic transformation of molecules Separation techniques for MOFs and insoluble compounds Magnetic properties, application of MOFs and coordination polymers A discussion of the increasing use of molecular dynamics simulations, and the need to prepare application specific configurations
Course Assessment
Continuous Evaluation 25% Mid Semester 25% End Semester 50%
Course no: Open course HM Course ASL –601 (Y/N) (Y/N) Type of course Course Title Mechanics of Composite Materials Course Coordinator Course objectives: POs Semester Contact Hours
Autumn: Lecture 3
DC (Y/N)
Tutorial
Spring Practical
0
0
DE (Y/N)
Credits 3
Prerequisite course code as per proposed course numbers Prerequisite credits Equivalent course codes as per proposed course and old course Overlap course codes as per proposed course numbers Text Books: 1.
2.
3.
4.
5.
Title Author Publisher Edition Title Author Publisher Edition Title Author Publisher Edition Title Author Publisher Edition Title Author Publisher Edition
"Composite materials and their use in structures." Vinson, Jack R., and Tsu-Wei Chou. (1975) Composite materials handbook., Schwartz, Melvin M. McGraw-Hill 1984. Analysis and design of structural bonded joints. (AU), . ong, Liyong, and Grant P. Steven. Univ. of Sydney, New South Wales 1999 et al. Engineering mechanics of composite materials. Daniel, Isaac M., New York: Oxford university press Vol. 3. , 1994. Interlaminar response of composite materials. Pagano, Nicholas J., ed. Elsevier , 2012
Reference Book: 1.
2.
Content
Title Author Publisher Edition Title Author Publisher Edition Introduction: Classification and characteristics of composites, Conventional vs. Composite materials, Advantages and limitations, Salient applications in various fields, Fabrication technologies. Micromechanics: Determining fibre volume fraction, Properties of matrix and reinforcement materials, micro-mechanic relations, determination of strength and stiffness, Environmental effects, Hygro-thermal behavior Macro-Mechanics: Basic stress-strain relationships for anisotropic materials, engineering constants for orthotropic materials, stress-strain relations for a lamina of arbitrary orientation, effective moduli, invariant properties of an orthotropic lamina, Strength of an orthotropic lamina. special cases of laminate stiffness, laminate strength analysis, failure theories for lamina, concept of inter-laminar stresses and delamination Analysis of Composite Structures: Classical lamination theory, shear deformation theories, Governing differential equations for Bending, Buckling and Vibration of Laminated Plates. Failure theories and Damage mechanics: Failure mechanisms, maximum stress theory, maximum strain theory, Tsai-Hill theory, Tensor polynomial failure criterion, first ply failure theory, mesoscale composite damage theory based on continuum damage mechanics. Characterization
and
Testing:
Characterization
of
Determination of Tensile, Compressive & shear strength
Course Assessment
Continuous Evaluation 25% Mid Semester 25% End Semester 50%
fiber
&
matrix,
Course no: Open course HM Course ASL –603 (Y/N) (Y/N) Type of course Course Title Nanomaterials and Nanocomposites Course Coordinator Course objectives: POs Semester
Autumn: Lecture
Contact Hours
3
DC (Y/N)
Tutorial
Spring Practical
0
0
DE (Y/N)
Credits 3
Prerequisite course code as per proposed course numbers Prerequisite credits Equivalent course codes as per proposed course and old course Overlap course codes as per proposed course numbers Text Books: 1.
Title
2.
Author Publisher Edition Title
3.
Author Publisher Edition Title
4.
Author Publisher Edition Title
Cao, Guozhong. Synthesis, Properties and Applications. Imperial college press, London, 2004
Ozin, Geoffrey A., André C. Arsenault, and Ludovico Cademartiri.Nanochemistry: a chemical approach to nanomaterials. Royal Society of Chemistry, 2009.
Gogotsi, Yury, and Volker Presser, eds. Carbon nanomaterials. CRC Press, 2013.
Zhang, Jin Z. Optical properties and spectroscopy of nanomaterials. Singapore: World Scientific, 2009.
Author Publisher Edition
5.
Reference Book: 1.
2.
Content
Course Assessment
Title Author Publisher Edition Title Author Publisher Edition Title Author Publisher Edition Fundamentals: Dimensional discretion, shape, morphology of nanostructures Crystalline and hybrid nanomaterials, defects. Effect of size, shape, and material Thermodynamics and surface effects: Gibbs free energy, entropy, adsorption and absorption, surface reconstruction  Metallic and semiconductor nanoparticles. Metallic nanoparticles, surface effects, Mie theory and absorbance, optical properties of metallic (e.g., silver and gold) nanoparticles, applications, Semiconductor nanoparticles, size-quantization effect, energy diagram, synthesis, Ostwald ripening, focusing and defocusing of particle size distribution, examples (e.g., CdSe, CdS etc.), applications in superstructures, LEDs, solar cells, and bio-labeling Nanophotonic and nanomagnetic materials: Localized and bulk surface plasmons, alloy (metal-metal, metal-dielectric, and metal semiconductor) nanomaterials, graphene, core-shell nanostructures, synthesis, Magnetic properties of nanoparticles, ferrofluidic magneto-electronics, spintronics, Nanolithography, scanning probe lithography, Case study/design on nanodevices such as nanophotonic sensors Other applications such as solar cell with nanoplasmonics concept. Continuous Evaluation 25% Mid Semester 25% End Semester 50%
Course no: ASL –605 Type of course Course Title Course Coordinator Course objectives:
Open course (Y/N)
HM Course (Y/N)
DC (Y/N)
DE (Y/N)
Advanced Photonic Materials and Devices
POs Semester
Autumn: Lecture
Contact Hours
3
Tutorial
Spring Practical
0
0
Credits 3
Prerequisite course code as per proposed course numbers Prerequisite credits Equivalent course codes as per proposed course and old course Overlap course codes as per proposed course numbers Text Books: 1.
2.
3.
4.
5.
Title Author Publisher Edition Title Author Publisher Edition Title Author Publisher Edition Title Author Publisher Edition Title Author Publisher Edition
Photonics: Optical Electronics Communications A. Yariv and P. Yeh, Oxford University Press (6th ed.), (2007). Fundamentals of Photonics B. E. A. Saleh and M. C. Teich, John Wiley & Sons (2nd ed.), (2007) Elements of Photonics (Vol. II), K. Iizuka, Wiley-Interscience (2002) Photonic Devices, J. M. Liu Cambridge University Press (2005).
in
Modern
Reference Book: 1.
2.
Content
Title Author Publisher Edition Title Author Publisher Edition Review of Ray Optics and Wave Optics: Optical fields and Maxwell’s equations, Harmonic fields, polarization, propagation of light in isotropic and anisotropic media, Gaussian beam, Reflection and refraction, dispersion, phase and group velocities, material dispersion Photon nature of light, wave-particle duality, Resonant Optics: Optical resonator, fundamentals, examples, and applications Plane mirror resonators, spherical mirror resonators Radiation-Atom Interaction: Interaction of radiation with atomic systems, atomic susceptibility, atomic transitions; Einstein coefficients, laser oscillations, specific laser systems, rate equations, Methods of pulsing lasers and advanced laser systems Electro-Optics and Magneto-optics: Principles, Electro-optics of anisotropic materials, Electro-optics of liquid crystal materials, photo-refractive materials, Principles of Magneto-optics, Kerr effect, materials and applications Non-linear Optics and Devices: Second and third order Non-linear optical materials, Coupled wave theory, anisotropic non-linear materials, Dispersive non-linear materials, solitons Fiber-Optic Systems: Guided wave optics, modes, planar optical waveguides, rectangular optical waveguides, devices, Modes and dispersion in optical fibers, materials for optical fibers, doped fibers Fiber optic devices, sensors, Micro-structured materials, photonic crystals, photonic crystal fibers, modern lenses, Fluorescent, photo-luminescent, chemi-luminescent, and phosphorescent materials
Course Assessment
Continuous Evaluation 25% Mid Semester 25% End Semester 50%
