Advanced Ceramics
1. General
1.1 TITLE: Advanced Ceramics
1.2 COURSE NUMBER: DE.MS404.15
1.3 CREDITS: 3-0-0 - Credit 9
1.4 SEMESTER -OFFERED: Even
1.5 Prerequisite: Physical Behaviour of Materials, Crystallography & Crystal Structures
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
To provide advanced understanding of the ceramic materials, their synthesis, properties and application
3. COURSE CONTENT
Ceramic powder synthesis methods: Solid state reaction method, chemical routes: Coprecipitation, spray drying, freeze drying, sol-gel method, hydrothermal and combustion. Microwave synthesis.
Characterzation of powders: Size and surface area.
Green Body Forming: dry pressing, slip and tape casting, extrusion, injection molding and sol-gel sintering. Hot pressing. Microwave sintering. Powder coating, flame and plasma spraying. Electrodeposition.
Point defects in ionic compounds. Effect of partial pressure of oxygen and temperature on defect concentration. Non-stoichiometry. Effect of alliovalent impurities on concentration of defects. Electronic properties of ceramic materials.
Symmetry and other criteria of ferroelectricity, ferroelectric transitions in BaTiO3, PbTiO3 and other related materials. Effect of compositional modifications and grain refinement. Relaxor ferroelectrics. Performance categories of ceramic capacitors with typical compositions. Powder synthesis, electroding and packaging of discrete, multilayer and barrier layer capacitors.
Symmetry considerations and equations of state for piezoelectric and electrostrictive effects. Poled ferroelectric ceramics. Measurement of coupling factor and strain coefficient. Phase diagram, preparation and properties of PZT ceramics.
Piezoelectric transducers, Motors, Piezoelectric positioners, loud speakers and gas igniters.
Pyroelectric and electro-optic ceramics and their applications.
NTC and PTC thermistors, ZnO varistors, and their applications.
4. READINGS
4.1 TEXTBOOK:
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Electro ceramics: Materials, Properties, Applications, A.J. Moulson and J.M. Herbert
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Ferroelectric Devices, K. Uchino
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Ceramic Materials for Electronics; Processing, Properties, and Applications, R.C. Buchanan
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Piezoelectric Ceramics, B. Jaffe W.R. Cook and H. Jaffe
4.2 REFERENCE BOOKS:
1. Ceramic Processing and Sintering, M.N. Rahman
5. OTHER SESSIONS
5.1 *TUTORIALS: 0:
5.2 *LABORATORY: 0:
5.3 *PROJECT: None:
6. ASSESSMENT (indicative only)
6.1 HA:: [xx% GRADE]
6.2 QUIZZES-HA: [xx% GRADE]
6.3 PERIODICAL EXAMS: [xx% GRADE]
6.4 *PROJECT: [xx% GRADE]
6.5 FINAL EXAM: [xx% GRADE]5. OTHER SESSIONS
7. OUTCOME OF THE COURSE:
Science of Ceramics
1. General
1.1 TITLE: Science of Ceramics
1.2 COURSE NUMBER: DE.MS405.15
1.3 CREDITS: 3-0-0 - Credit 9
1.4 SEMESTER -OFFERED: Even
1.5 Prerequisite: Physical Behaviour of Materials, Crystallography & Crystal Structures
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
To provide advanced understanding of the ceramic materials, their synthesis, properties and application.
3. COURSE CONTENT (class breakup to be discussed with AKS/DP/CR
Bonding and crystal structure of ceramics. Effect of bonding, crystal structure and microstructure on physical properties of ceramics.
Synthesis of ceramic powder and nanoparticles and their consolidation. Sintering and grain growth mechanisms.
Theoretical fracture strength, Griffith’s theory of brittle fracture, toughness and fracture toughness, factors influencing the strength of ceramic materials. Toughening mechanisms, transformation toughening, R-curve behaviour and designing with ceramics. Weibull modulus. Creep and fatigue in ceramics materials.
Thermal expansion, thermal conductivity, thermal stresses and thermal shock resistance. Spontaneous microcracking. Thermal tempering.
4. READINGS
4.1 TEXTBOOK:
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Electroceramics: Materials, Properties, Applications, A.J. Moulson and J.M. Herbert
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Ferroelectric Devices, K. Uchino
-
Ceramic Materials for Electronics; Processing, Properties, and Applications, R.C. Buchanan
-
Piezoelectric Ceramics, B. Jaffe W.R. Cook and H. Jaffe
4.2 REFERENCE BOOKS:
1. Ceramic Processing and Sintering, M.N. Rahman
5. OTHER SESSIONS
5.1 *TUTORIALS: 0:
5.2 *LABORATORY: 0:
5.3 *PROJECT: None:
6. ASSESSMENT (indicative only)
6.1 HA:: [xx% GRADE]
6.2 QUIZZES-HA: [xx% GRADE]
6.3 PERIODICAL EXAMS: [xx% GRADE]
6.4 *PROJECT: [xx% GRADE]
6.5 FINAL EXAM: [xx% GRADE]5. OTHER SESSIONS
7. OUTCOME OF THE COURSE:
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List of Electives DE3
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UG-CRC Code
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Course Code
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Course Name
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L–T–P
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Credits
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DE.MS406.15
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MS406
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Industrial Polymers
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3
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0
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0
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9
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DE.MS407.15
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MS407
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Thin Films, Interfaces & Multilayers
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3
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0
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0
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9
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Industrial Polymers
1. General
1.1 TITLE: Industrial Polymers
1.2 COURSE NUMBER: DE.MS406.15
1.3 CREDITS: 3-0-0 - Credit 9
1.4 SEMESTER -OFFERED:
1.5 Prerequisite: Polymeric Materials
1.6 Syllabus Committee Members: 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
Industrial preparation of polymeric materials and structure property relationship. Uses of polymers in various industries e.g. tyre, paint, adhesive, packaging, energy, data storage, and biomedical sectors understanding the property requirement.
3. COURSE CONTENT
Unit 1 (2 Lectures)
Origin of Polymer Science – a brief history; Classification of polymers - origin (plant based, petroleum and synthetic route), molecular architecture, and processing
Unit 2 (8 Lectures)
Industrial preparation, structure property relationship and use of thermoset polymers (phenol-formaldehyde, amino-formaldehyde, epoxides, polyamides, polyesters and polyurethanes);
Industrial preparation, structure property relationship and use of thermoplasts (polyolefins, poly(vinyl chloride), ion exchange resin, polystyrene, poly(tetrafluoro ethylene), acrylics, polyamides, polycarbonate, polyacetal, cellulose, polyphenylene, polysulphone and polyesters);
elastomer and fibres (preparation, structure property relation, use and trade names);
Unit 3 (4 Lectures)
Tyre science: classification, diagonal, radial and bias belted tyres, tyre textile, formulation and properties, tyre production, speed and load indices of tyre
Unit 4 (4 Lectures)
Adhesive science: Type of adhesives; material, advantage and disadvantages of adhesive; mechanism of adhesion; surface energy and wetting phenomena; joint strength;
Unit 5 (8 Lectures)
Paints and coatings: Components and ingredients; application (drying paint & dry film); Pigment (type, property, dispersion, colour and formulation); Solvents (type and properties); Paint additives (controlling flow behaviour and chemical reactions); Lacquers (acrylics, cellulose, emulsion paints); Oil and alkyd paints, thermoset paints; Epoxy and polyurethane coatings;
Unit 6 (4 Lectures)
Polymers in energy sector: Solid electrolytes, fuel cell membrane and application in renewable energy devices
Unit 7 (2 Lectures)
Polymers in storage device: Optical media and data storage device
Unit 8 (4 Lectures)
Polymers in packaging: Types of packaging and use of individual polymers; Packaging Techniques (Thermoforming, Co-extrusion, Extrusion-stretch blow molding, BOPP films); Performance properties (bursting, tensile, tearing strength, drop test, puncture test, impact test)
Unit 9 (2 Lectures)
Polymers in Biomedical uses: Implant materials; polymers in drug delivery
4. READINGS
4.1 TEXTBOOK:
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Engineering Plastic Handbook by J. M. Margolis, McGraw-Hill Company
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Food Packaging Principles and Practice by Gordon L. Robertson, CRC Press
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The Science and Technology of Rubber by J. E. Mark, B. Erman, F.R. Eirich, Elsevier
4.2 REFERENCE BOOKS:
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Synthetic Fibres by J. E. Macintyre, Wood Head Fiber Science Series, UK
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Adhesion and Adhesives Technology by A. V. Pocius, H. Carl, Hanser-Verlag
5. OTHER SESSIONS
5.1 *TUTORIALS: 0:
5.2 *LABORATORY: 0:
5.3 *PROJECT: None:
6. ASSESSMENT (indicative only)
6.1 HA:: [xx% GRADE]
6.2 QUIZZES-HA: [xx% GRADE]
6.3 PERIODICAL EXAMS: [xx% GRADE]
6.4 *PROJECT: [xx% GRADE]
6.5 FINAL EXAM: [xx% GRADE]
7. OUTCOME OF THE COURSE:
Large scale production of polymers used for engineering and daily use. Polymer used in various industries are highlighted with the understanding of property requirement and associated science.
Thin Films, Interfaces & Multilayers
1. General
1.1 TITLE: Thin Films, Interfaces & Multilayers
1.2 COURSE NUMBER: DE.MS407.15
1.3 CREDITS: 3-0-0 - Credit 9
1.4 SEMESTER -OFFERED: Even
1.5 Prerequisite: None
1.6 Syllabus Committee Members: 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
To provide the knowledge about thin films, their uniqueness over the normal bulk materials. A brief knowledge about synthesis methods, properties of thin films, multilayers and hetro-structures and their applications.
3. COURSE CONTENT
Unit I: Thin films (22 Lectures)
Thin-Film Fabrication: Epitaxial, grain oriented and polycrysalline thin films, fundamentals of vacuum instruments. Thermal and electron beam evaporation. Sputtering methods: DC, RF and Magnetron. Laser ablation. Chemical vapour deposition. MOCVD. Electro-deposition. Molecular beam epitaxy. Langmuir–Blodgett Films.
Morphology Maps, Interfaces, Grain Boundaries
Unit I: Multilayers (17 Lectures)
Multilayer Materials: Strength and Toughness, Critical Thickness
Hardness of Multilayers
Stoichiometric Optimization of Physical Parameters
Ionic Solutions, Solid–Electrolyte Interface
X-ray Mirrors, Quasiperiodic Nonlinear Optical Crystals
Graphite Intercalated Compounds
4. READINGS
4.1 TEXTBOOK:
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Hand book of thin films by Maisel
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Thin Film by A. Goswami
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Materials Science of Thin Films by Milton Ohring
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Thin Film Materials: Stress, Defect Formation and Surface Evolution by L. B. Freund
4.2 REFERENCE BOOKS:
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Handbook of Thin Film Deposition, by Krishna Seshan
5. OTHER SESSIONS
5.1 *TUTORIALS: 0:
5.2 *LABORATORY: 0:
5.3 *PROJECT: None:
6. ASSESSMENT (indicative only)
6.1 HA:: [xx% GRADE]
6.2 QUIZZES-HA: [xx% GRADE]
6.3 PERIODICAL EXAMS: [xx% GRADE]
6.4 *PROJECT: [xx% GRADE]
6.5 FINAL EXAM: [xx% GRADE]
7. OUTCOME OF THE COURSE:
Undergraduate Project
1. GENERAL
1.1 TITLE:: UG Project
1.2 *COURSE NUMBER (if known):: DP.MS391.15
1.3 CREDITS:: [0-0-5] 5 Credits
1.4 SEMESTER-OFFERED:: Sixth (IV)
1.5 PRE-REQUISITES::
2. OBJECTIVE:: The specific objectives of the course could depend on the problem definition for the project but the overall performance will be measured on the following criteria.
Course Contents:
UNIT-I: Literature survey- Students will be having a brief literature survey on the topic selected by the allotted instructor/supervisor. A brief draft should be prepared out this activity.
UNIT-II: Problem Identification - An appropriate/feasible problem should be selected for the problem.
UNIT-III: Experimental/Theoretical work- The work needs to necessarily be novel or original. A proper strategy should be worked out to solve/explore the problem undertaken. Accordingly, experiments should be planned well in advance, executed, followed by data analysis and interpretation.
UNIT-IV: Presentation/Demonstration- A presentation should be made for the work done during the semester having clear identification of problem/s undertaken, work done, objectivity of data analysis and a summary of the important results in both a seminar and report.
A combination of the above criteria can be used to grade the work. Typically, the following guidelines could be helpful for projects taken up as part of different semesters.
Evaluation procedure: Literature Survey 25%, Experimental/Theoretical work 50%, Demonstration and Presentation 25%.
3. COURSE TOPICS:: Choice of student and the instructor.
4. READINGS 4.1
TEXTBOOK:: Instructor’s choice.
4.2 *REFERENCE BOOKS:: Instructor’s choice.
5. OTHER SESSIONS
5.1 *TUTORIALS:: No
5.2 *LABORATORY:: Yes
5.3 *PROJECT:: Yes
6. ASSESSMENT (indicative only)
6.1 HA:: [0% GRADE]
6.2 QUIZZES-HA:: [0% GRADE]
6.3 PERIODICAL EXAMS:: [0% GRADE]
6.4 *PROJECT:: [100% GRADE]
6.5 FINAL EXAM:: [0% GRADE]
7. OUTCOME OF THE COURSE:: Project goals as defined by the instructor.
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Section-4AC2
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Materials Science and Technology: 5-Year IDD VII-Semester
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DC.MS408.15
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MS408
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Mechanical Behaviour of Materials
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3
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0
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2
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11
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DE.MS409.15
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MS409
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Composite Materials/(course from List DE4)
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3
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0
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0
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9
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OE.?????.15
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?????
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Open elective
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3
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0
|
0
|
9
|
OE.?????.15
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?????
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Open elective
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3
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0
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0
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9
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IH/LM.H?0?.14
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HU/LM???
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Humanities/Language & Management Course
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3
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0
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0
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9
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DP.MS491.15
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MS491
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UG Project
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0
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0
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10
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10
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Total
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15
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0
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12
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57
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GY.PE107.14
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PE107
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Sports/Creative Practice #
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0
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0
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5
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5
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1. General
1.1 TITLE: Mechanical Properties of Materials
1.2 COURSE NUMBER: DC.MS408.15
1.3 CREDITS: 3-0-0 - Credit 9
1.4 SEMESTER -OFFERED: Odd
1.5 Prerequisite: Crystallography & Crystal Structures
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
To provide basic understanding of the mechanical behavior of materials, elastic and inelastic properties of materials, role of defects and dislocations on the mechanical properties and understanding of various mechanism of strengthening of material.
3. COURSE CONTENT
Mechanical testing: Concept of stress/strain. Tensile, compression, shear, hardness and impact testing.
Measurement of stress and strain: Load cells. Optical, electrical and electronic strain measuring devices.
Nondestructive testing techniques: Ultrasonic testing. Radiography. Acoustic emission. Eddy current testing. Liquid penetration technique. Magnetic method of crack detection.
Elastic behaviour of materials: Atomic basis. Anelasticity. Thermoelastic effect. Damping capacity. Thermal expansion, Thermal stresses and thermal shock resistance.
Structural imperfections: Point defects in metals and ionic crystals. Theoretical yield strength. Dislocations and their types. Energy of dislocations, their interaction and movement in crystals. Dislocation multiplication. Dislocations in crystals. Partial dislocations and stacking faults. Role of dislocations in plastic deformation.
Plastic deformation of materials: Slip and twinning. Concept of critical resolved shear stress.
Yield point, work hardening and plastic instability. Annealing and recovery phenomena. Strengthening mechanisms: Grain refinement, solute and precipitation hardening.
Theoretical fracture strength, Griffith’s theory of brittle fracture, toughness and fracture toughness, factors influencing the strength of ceramic materials. Toughening mechanisms, transformation toughening, R-curve behaviour and designing with ceramics. Weibull modulus. Creep and fatigue in ceramics and metallic materials.
Thermal expansion, thermal conductivity, thermal stresses and thermal shock resistance. Spontaneous microcracking. Thermal tempering.
Brief Introduction of metal forming processes: Rolling, forging, extrusion, drawing and sheet metal forming.
4. READINGS
4.1 TEXTBOOK:
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Materials Science & Engineering: An Introduction, W.D. Callister. Jr.
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The Science and Engineering of Materials, D.R. Askeland.
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Mechanical Metallurgy, G.E. Dieter.
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Materials Science and Engineering, V. Raghavan.
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Engineering Materials Part 1 & 2, Ashby and D.R.H. Jones.
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