Syllabus booklet 5-Years Integrated Dual Degree Programme
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7. OUTCOME OF THE COURSE: Students get idea about the advanced characterization methods involved in materials characterization. This course also serves as supporting course for the UG Project and M. Tech. Dissertation.
Organic Electronics & Organic Conductors 1. General 1.1 TITLE: Organic Electronics & Organic Conductors 1.2 COURSE NUMBER: DE.MS503.15 1.3 CREDITS: 3-0-0 - Credit 9 1.4 SEMESTER -OFFERED: VIII (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: Understanding of organic conducting and charge transfer materials including their synthesis, fabrication of devices and their applications in organic electronics. 3. Course Content Unit-1: Introduction of organic semiconductor: Basic concepts. Molecular materials and their classifications, Small molecules and polymers. Liquid crystals. (5 Lectures) Unit-2:Film growth, interface and transport properties (7 Lectures) Charge transport phenomena in organic semiconductors: Drift velocity, Mobility, Mobility measurement techniques. Heterojunction: organic-organic, bulk heterojunction, organic-inorganic, Organic thin film deposition technique: LB thin film, thermal evaporation, spin coating method. Unit-3: Organic thin film device and application: (7 Lectures) OFET, OPV, OLED, Display devices and optical data storage. Photochromism, electrochromism and their applications. Unit-4 (6 lectures) Introduction of Conducting Polymers: Type of conducting polymers. Basic principle and structure. Unit-5 (5 Lectures) Synthesis: Chemical and electrochemical routes of synthesis. Doping of conjugated polymers. Delocalized electronic states of conjugated polymers. Unit-6 (3 Lectures) Electrical Property: Electronic conduction in conjugated polymers. Transport of charge in conducting polymers. Unit-7 (6 Lectures) Applications: Charge storage devices based on conducting polymers. Construction of modified electrodes. Conducting polymer as intermediate layer and matrices for immobilization of chemicals. Sensor and biosensor applications of conducting polymers. Test Books Suggested:
Reference Books Suggested:
5.1 *TUTORIALS: 0:
5.3 *PROJECT: None: 6. ASSESSMENT (indicative only)
Concept of organic conductors and device applications. Diffraction Techniques in Materials Science 1. General 1.1 TITLE: Diffraction Techniques in Materials Science 1.2 COURSE NUMBER: DE.MS504.15 1.3 CREDITS: 3-0-0 - Credit 9 1.4 SEMESTER -OFFERED: Odd 1.5 Prerequisite: Crystallography & Crystal Structures 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 advance understanding of crystallographic principles for structural analysis of crystalline materials, basics of mathematical crystallography, space group symmetries as well as application of various diffraction methods for structure determination and analysis. 3. COURSE CONTENT UNIT I: (12 Lectures) Interaction of x-rays with matter. Laue equations. Bragg’s law. Reciprocal lattice concept and its applications to rotation, Laue and Debye Scherrer techniques. Atomic scattering factor and structure factor. Lorentz-Polarization factor, multiplicity factor, temperature factor. Lattice and space group extinctions. Phase problem and determination of crystal structures. Elementary ideas about electron and neutron diffraction.
Debye Scherrer, Guinier and Bragg-Brentano geometries for powder diffractometers. General intensity expression for powder diffraction. Rietveld refinement technique. Quantitative phase analysis and microstructure determination. Limitations of powder method. Single crystal diffractometers. UNIT III: (6 Lectures) General procedure for working out the details of space groups with illustrations. Wyckoff positions. Elementary ideas about magnetic groups. UNIT IV: (8 Lectures) Principles of crystal structure analysis. Structure factor calculations. Space group extinctions. Experimental determination of space group and inversion symmetry. Electron density functions. Phase problem. Patterson functions. Refinement procedures. Direct methods in crystallography. 4. READINGS 4.1 TEXTBOOK:
4.2 REFERENCE BOOKS: 1. International Table of Crystallography Vol.3 5. OTHER SESSIONS 5.1 *TUTORIALS: 0: 5.2 *LABORATORY: 0: 5.3 *PROJECT: None: 6. ASSESSMENT (indicative only)
Students get an advance understanding of crystallographic principles for structural analysis of crystalline materials, basics of mathematical crystallography, space group symmetries as well as application of various diffraction methods for structure determination and analysis.
M.Tech. Project 1. GENERAL 1.1 TITLE:: M.Tech. Project 1.2 *COURSE NUMBER (if known):: DP.MS691.15 1.3 CREDITS:: [0-0-25] 25 Credits 1.4 SEMESTER-OFFERED:: Ninth (IX) 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 and to the best possible extent, an extension of the previous projects, so that a conclusive study can be made. 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.
Nanostructured Materials 1. General 1.1 TITLE: Nanostructured Materials 1.2 COURSE NUMBER: DC.MS505.15 1.3 CREDITS: 3-0-0 - Credit 9 1.4 SEMESTER -OFFERED: Odd 1.5 Prerequisite: Physical Behaviour of Materials + Materials Characterization 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: Provide the techniques to synthesize the materials with reduced dimension, their characterizations with different techniques and an understanding of physical properties of the materials when dimension is reduced from bulk (3 dimensions) to zero dimension. 3. Course Content Unit I (5 Lectures) Classification of Nanomaterials and Nanostructures: Carbon Nanotube, fullerene, Graphene, Metamaterials Unit II (15 Lectures) Preparation methods: Physical Methods: High energy ball milling and mechanical attrition, Lithography, Molecular beam epitaxy, Thermal evaporation. Sputtering. Laser ablation. Chemical Methods: Thermal and ultrasound decomposition methods. Reduction methods. Coprecipitation, Combustion Methods, sprays & freeze drying, sol-gel and hydro/solvothermal methods. Chemical vapour deposition. Microwave assisted synthesis. Thermal spraying. Electro and Photochemical synthesis. Template Synthesis. Unit III (10 Lectures) Properties: Dimensionality effects on electrical, electronic, optical, magnetic & dielectric properties. Unit III (4 Lectures) Characterization: Microstructure analysis using TEM, SEM & XRD. Unit V (5 Lectures) Application of Nanostructures: Single electron tunneling. Applications in LED, infrared detectors and quantum dot lasers. Biological applications 4. READINGS 4.1 TEXTBOOK:
5. OTHER SESSIONS 5.1 *TUTORIALS: 0:
5.3 *PROJECT: None: 6. ASSESSMENT (indicative only)
After completion of the course the students are supposed to a have a brief account of different techniques to synthesize the materials with reduced dimension, their characterizations with different techniques and an understanding of physical properties of the materials when dimension is reduced from bulk (3 dimensions) to zero dimension. Functional Materials 1. General 1.1 TITLE: Functional Materials 1.2 COURSE NUMBER: DE.MS506.15 1.3 CREDITS: 3-0-0 - Credit 9 1.4 SEMESTER -OFFERED: Odd 1.5 Prerequisite: Crystallography & Crystal Structures, Electrical & Electronic Ceramics 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 acquaint the students with different class of functional materials, basic understanding of functional behaviour, structure property correlations and the advance applications of functional materials. 3. COURSE CONTENT UNIT I: (3 Lectures) Definition and scope of functional materials. UNIT II: (6 Lectures) Shape memory effects and shape memory alloys. Novel magnetic shape memory alloys. Invar alloys. UNIT III: (9 Lectures) Functional materials in computer memory devices: Ferroelectric RAM. Phase change materials in optical media storage devices. UNIT IV: (9 Lectures) Giant and colossal magnetoresistance materials and their applications. Multiferroic materials and their applications as sensors and actuators. Functionally graded materials and their applications. UNIT V: (9 Lectures) Hydrogen storage materials and their applications. Membranes and Fuel Cell electrode materials. UNIT VI: (3 Lectures) Smart gels: Materials, synthesis and applications. 4. READINGS 4.1 TEXTBOOK: 1. Advanced Functional Materials: Electrical, Dielectric, Electromagnetic, Optical and Magnetic Applications by Deborah D. L. Chung 2. Advanced Functional Materials, Volume 2: A Perspective from Theory and Experiment by B. Sanyal and O. Eriksson 3. Functional Materials: Preparation, Processing and Applications by S. Banerjee 4. Physics of Functional Materials by Hasse Fredriksson and Ulla Åkerlind
Shape Memory Alloy Engineering: For Aerospace, Structural and Biomedical Applications by Leonardo Lecce and Antonio Concilio 5. OTHER SESSIONS 5.1 *TUTORIALS: 0: 5.2 *LABORATORY: 0: 5.3 *PROJECT: None: 6. ASSESSMENT (indicative only)
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