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B-TECH-M-TECH-DUAL-DEGREE in Metallurgy Engineering Materials Science And Engineering at Indian Institute of Technology Indore
Indore, Madhya Pradesh
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About the Specialization
What is Metallurgy Engineering (Materials Science and Engineering) at Indian Institute of Technology Indore Indore?
This Metallurgy Engineering (Materials Science and Engineering) program at IIT Indore focuses on a comprehensive understanding of materials, from their atomic structure to processing and application. It emphasizes the interdisciplinary nature of materials science, covering metals, ceramics, polymers, and composites. The program is vital for India''''s growing manufacturing, defense, and energy sectors, driving innovation in material design and performance.
Who Should Apply?
This program is ideal for highly motivated science and engineering graduates seeking to specialize in materials science, research, and development. It suits students aspiring for careers in core engineering industries, R&D labs, or further academic pursuits. A strong foundation in physics, chemistry, and mathematics is a prerequisite for success in this challenging yet rewarding field.
Why Choose This Course?
Graduates of this program can expect diverse career paths in India, including roles in PSUs like SAIL, DRDO, ISRO, and private firms in automotive, aerospace, and electronics sectors. Entry-level salaries typically range from INR 6-12 LPA, with experienced professionals earning significantly more. The dual degree offers a competitive edge, fostering advanced analytical and research skills crucial for leadership roles and innovation.
Student Success Practices
Foundation Stage
Master Core Science and Engineering Fundamentals- (Semester 1-2)
Focus intensely on Calculus, Physics, Chemistry, and Engineering Mechanics. These foundational subjects are crucial for understanding advanced materials concepts. Utilize tutorials, problem-solving sessions, and peer study groups to solidify knowledge. Regular practice of numerical problems from textbooks and previous year papers is highly recommended.
Tools & Resources
NPTEL courses for foundational subjects, Khan Academy, Reference textbooks (e.g., Resnick Halliday for Physics, NCERT for Chemistry), IIT Indore''''s academic support centers
Career Connection
A strong foundation ensures ease in understanding advanced departmental courses, critical for interviews and research in core materials industries.
Develop Programming and Engineering Graphics Skills- (Semester 1-2)
Become proficient in Python programming through the ''''Introduction to Computing'''' course and practice regularly on platforms like HackerRank or CodeChef. Simultaneously, excel in Engineering Graphics, as visualization and CAD skills are vital for material design and analysis. Practical application in mini-projects is encouraged.
Tools & Resources
Python documentation, Jupyter Notebooks, AutoCAD/SolidWorks tutorials, Online coding challenge platforms
Career Connection
Computational skills are increasingly vital in materials science for modeling, simulation, and data analysis. Engineering graphics aids in material component design and manufacturing.
Engage with Departmental Introductory Courses Early- (Semester 2)
Pay close attention to ''''Introduction to Metallurgy'''' and ''''Materials Lab-I''''. Seek opportunities to visit departmental labs, interact with senior students and faculty, and understand the practical aspects of materials science. This early exposure helps in identifying areas of interest for future specialization.
Tools & Resources
Departmental lab visits, Faculty office hours, Student mentorship programs, Basic materials science textbooks
Career Connection
Early engagement builds fundamental material knowledge and practical skills, setting the stage for future projects and internships in metallurgy and materials industries.
Intermediate Stage
Deep Dive into Core Materials Science Concepts- (Semester 3-5)
Master subjects like Thermodynamics, Structure, Phase Transformations, and Mechanical Behavior of Materials. Actively participate in labs (Materials Lab-II, Computational Materials Engineering Lab) to gain hands-on experience with characterization and computational tools. Form study groups to tackle complex theoretical and numerical problems.
Tools & Resources
ASM Handbook, MATLAB/Python for computational exercises, Specialized software like Thermo-Calc (if accessible), Research papers on specific topics
Career Connection
Strong theoretical and practical knowledge in core materials concepts is essential for R&D roles, material selection, and failure analysis in various industries.
Seek Early Industry Exposure and Internships- (Summer breaks after Sem 4 and/or Sem 6)
Actively apply for summer internships after your 2nd or 3rd year. Look for opportunities in manufacturing, R&D, and core materials companies in India (e.g., steel plants, automotive manufacturers). An industrial training provides invaluable practical experience and helps connect theoretical knowledge to real-world applications.
Tools & Resources
IIT Indore''''s Career Development Cell, LinkedIn, Naukri.com, Company websites for internship programs
Career Connection
Internships are critical for networking, gaining practical skills, and improving placement prospects by demonstrating industry readiness.
Explore Departmental Electives and Research Projects- (Semester 5-6)
Thoughtfully choose departmental electives to explore specialized areas like Nanomaterials, Biomaterials, or Surface Engineering based on your interests. Engage in minor research projects with faculty to gain experience in experimental design, data analysis, and scientific writing, building a strong research profile.
Tools & Resources
Faculty research profiles, Departmental seminar series, Access to advanced lab equipment, Scientific journals
Career Connection
Specialized knowledge and research experience are highly valued for M.Tech thesis work, higher studies, and R&D positions in advanced materials sectors.
Advanced Stage
Focus on Thesis Research and Advanced Electives- (Semester 7-10)
Dedicate significant effort to your B.Tech and M.Tech thesis projects (Project-I, Project-II, Thesis Phase I & II). Collaborate closely with your supervisor, attend research seminars, and critically analyze scientific literature. Select M.Tech departmental electives that align with your thesis topic and career goals for deeper specialization.
Tools & Resources
Research databases (Scopus, Web of Science), Scientific writing software (LaTeX), Advanced characterization facilities, Mentorship from PhD scholars
Career Connection
A strong thesis project is a cornerstone for research careers, Ph.D. admissions, and demonstrating advanced problem-solving skills to potential employers.
Develop Professional Networking and Communication Skills- (Semester 7-10)
Attend national and international conferences, workshops, and industry events related to materials science. Network with professionals, researchers, and alumni. Refine your presentation and scientific communication skills, both written and oral, which are crucial for showcasing your research and professional capabilities.
Tools & Resources
Conference websites, Professional societies (e.g., IIM, MRS), LinkedIn for networking, IIT Indore''''s communication workshops
Career Connection
Networking opens doors to job opportunities, collaborations, and mentorship, while strong communication skills are indispensable for career progression in any field.
Prepare for Placements and Higher Studies- (Semester 7-10)
Start placement preparation early, focusing on technical aptitude, quantitative skills, and communication. Tailor your resume and cover letter to specific roles in materials, manufacturing, or R&D sectors. For higher studies, prepare for competitive exams like GATE, GRE, or TOEFL, and identify suitable universities and research groups.
Tools & Resources
Placement cell resources (mock interviews, resume reviews), GATE/GRE/TOEFL preparation material, Online aptitude tests, Alumni network for guidance
Career Connection
Proactive preparation ensures successful placements in leading companies or admission to prestigious graduate programs, securing a strong career trajectory.
Program Structure and Curriculum
Eligibility:
- Admission through JEE (Advanced) examination
Duration: 10 semesters / 5 years
Credits: 417 Credits
Assessment: Internal: 40-60%, External: 40-60%
Semester-wise Curriculum Table
Semester 1
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| MA101 | Calculus | Core | 8.5 | Real Numbers and Sequences, Functions of Single Variable, Functions of Several Variables, Partial Derivatives, Multiple Integrals |
| PH101 | Physics | Core | 8.5 | Classical Mechanics, Special Relativity, Quantum Mechanics, Statistical Physics, Electromagnetism |
| CE101 | Engineering Graphics | Core | 7 | Orthographic Projections, Isometric Projections, Sectioning and Auxiliary Views, Assembly Drawings, Computer Aided Drafting (CAD) |
| CH101 | Chemistry | Core | 8.5 | Quantum Chemistry, Spectroscopy Principles, Organic Reaction Mechanisms, Electrochemistry, Coordination Chemistry |
| HS101 | English for Communication | Core | 7 | Grammar and Syntax, Reading Comprehension, Academic Writing, Oral Communication, Presentation Skills |
| ES101 | Engineering Mechanics | Core | 8.5 | Force Systems and Equilibrium, Trusses and Frames, Friction, Kinematics of Particles, Work-Energy Principle |
| LA101 | Life Skills & Values | Core | 2 | Self-Awareness and Personal Growth, Ethical Decision Making, Social Responsibility, Interpersonal Communication, Stress Management |
Semester 2
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| CS101 | Introduction to Computing | Core | 8 | Programming in Python, Data Types and Operations, Control Structures, Functions and Modules, Basic Object-Oriented Concepts |
| MA102 | Linear Algebra & Differential Equations | Core | 8.5 | Vector Spaces, Linear Transformations, Matrices and Eigenvalues, Ordinary Differential Equations, Partial Differential Equations |
| PH102 | Quantum Physics & Applications | Core | 8.5 | Wave-Particle Duality, Schrödinger Equation, Atomic Structure, Solid State Physics, Semiconductor Devices |
| MM101 | Introduction to Metallurgy | Core | 8.5 | History of Metallurgy, Extraction Processes, Properties of Metals, Alloy Systems and Phase Diagrams, Materials Characterization |
| ME101 | Basic Mechanical Engineering | Core | 8.5 | Thermodynamics Fundamentals, Fluid Mechanics Basics, IC Engines, Refrigeration and Air Conditioning, Manufacturing Processes |
| EE101 | Basic Electrical Engineering | Core | 8.5 | DC Circuit Analysis, AC Circuit Analysis, Transformers, Electric Motors, Basic Electronics |
| MM102 | Materials Lab-I | Lab | 4.5 | Material Characterization Techniques, Mechanical Testing of Materials, Metallography and Microscopy, Heat Treatment Processes, Polymer Processing |
Semester 3
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| MA201 | Probability & Statistics | Core | 8.5 | Probability Theory, Random Variables, Probability Distributions, Statistical Inference, Regression Analysis |
| MM201 | Thermodynamics of Materials | Core | 8.5 | Thermodynamic Laws, Free Energy and Phase Equilibria, Solutions and Chemical Potentials, Phase Diagrams (Unary, Binary), Thermochemistry |
| MM202 | Structure of Materials | Core | 8.5 | Atomic Bonding, Crystal Structures, Crystal Defects, Diffusion in Solids, Polymers and Composites |
| MM203 | Fluid Dynamics and Heat Transfer | Core | 8.5 | Fluid Properties, Fluid Flow Equations, Boundary Layers, Conduction Heat Transfer, Convection and Radiation Heat Transfer |
| MM204 | Materials Lab-II | Lab | 4.5 | X-Ray Diffraction, Scanning Electron Microscopy (SEM), Transmission Electron Microscopy (TEM), Thermal Analysis (DSC, TGA), Spectroscopy Techniques |
| HSxxx | Humanities Elective-I | Elective | 7 | Social Sciences, Arts and Culture, Economics, Philosophy, History |
Semester 4
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| MM205 | Phase Transformations | Core | 8.5 | Nucleation and Growth, Diffusion Controlled Transformations, Martensitic Transformations, Solidification, Precipitation Hardening |
| MM206 | Mechanical Behavior of Materials | Core | 8.5 | Stress and Strain, Elastic and Plastic Deformation, Fracture Mechanics, Fatigue and Creep, Hardness and Toughness |
| MM207 | Extractive Metallurgy | Core | 8.5 | Ore Dressing, Pyrometallurgy, Hydrometallurgy, Electrometallurgy, Process Control in Extraction |
| MM208 | Computational Materials Engineering Lab | Lab | 4.5 | Thermodynamic Calculations, Phase Diagram Computations, Process Simulation, Data Analysis in Materials, Computational Tools (e.g., CALPHAD) |
| OPxxx | Open Elective-I | Elective | 8.5 | Interdisciplinary Topics, Programming, Business, Environmental Studies, Humanities |
| MM209 | Metallurgy & Materials Lab | Lab | 4.5 | Microstructural Analysis, Corrosion Testing, Powder Metallurgy Techniques, Polymer Characterization, Welding Processes |
Semester 5
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| MM301 | Materials Manufacturing | Core | 8.5 | Solidification Processing, Powder Metallurgy, Forming Processes, Welding and Joining, Additive Manufacturing |
| MM302 | Functional Materials | Core | 8.5 | Semiconducting Materials, Dielectric Materials, Magnetic Materials, Optical Materials, Smart Materials |
| MM303 | Corrosion and Degradation of Materials | Core | 8.5 | Electrochemistry of Corrosion, Types of Corrosion, Corrosion Protection, High Temperature Degradation, Environmental Effects |
| MM304 | Physical Metallurgy Lab | Lab | 4.5 | Heat Treatment Experiments, Phase Transformation Studies, Recrystallization Studies, Grain Size Analysis, Creep and Fatigue Testing |
| MM305 | Industrial Training/Internship | Project | 4.5 | Industry Exposure, Practical Skill Development, Project Implementation, Report Writing, Presentation Skills |
| DE-I | Departmental Elective-I | Elective | 8.5 | Advanced Materials Science, Metallurgical Processing, Surface Engineering, Biomaterials, Nanomaterials |
Semester 6
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| MM306 | Polymeric Materials | Core | 8.5 | Polymer Synthesis, Polymer Structure, Polymer Properties, Polymer Processing, Polymer Composites |
| MM307 | Ceramic Materials | Core | 8.5 | Ceramic Structures, Ceramic Processing, Mechanical Properties of Ceramics, Electrical Properties of Ceramics, Advanced Ceramics |
| MM308 | Modelling and Simulation in Materials | Core | 8.5 | First Principles Calculations, Molecular Dynamics, Phase Field Modeling, Finite Element Analysis (FEA), Data-driven Materials Science |
| MM309 | Manufacturing & Fabrication Lab | Lab | 4.5 | Casting and Foundry, Rolling and Forging, Machining Operations, Welding Techniques, Powder Processing |
| DE-II | Departmental Elective-II | Elective | 8.5 | Advanced Material Characterization, Nanomaterials and Nanotechnology, Biomaterials and Tissue Engineering, Additive Manufacturing of Materials, Surface Engineering |
| DE-III | Departmental Elective-III | Elective | 8.5 | Ferrous and Non-Ferrous Alloys, Composite Materials, Failure Analysis, Materials for Energy Applications, Thin Films and Coatings |
Semester 7
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| MM401 | Materials Characterization Techniques | Core | 8.5 | Electron Microscopy (SEM, TEM), X-ray Diffraction, Spectroscopic Techniques (XPS, FTIR), Thermal Analysis Methods, Mechanical and Tribological Testing |
| MM402 | Project-I | Project | 9 | Problem Identification, Literature Review, Experimental Design, Data Collection and Analysis, Project Report and Presentation |
| DE-IV | Departmental Elective-IV | Elective | 8.5 | Advanced Ceramics, Processing of Composites, Sustainable Materials, Metallurgical Failure Analysis, Electronic Materials |
| OPxxx | Open Elective-II | Elective | 8.5 | Entrepreneurship, Data Science, Environmental Engineering, Operations Research, Financial Management |
| MM7xx | Departmental Core (M.Tech)-I | Core | 9 | Advanced Thermodynamics of Materials, Kinetics of Materials Processes, Defects in Materials, Phase Transformations in Alloys, Computational Materials Design |
Semester 8
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| MM403 | Project-II | Project | 9 | Advanced Experimental Work, Numerical Simulations, Result Interpretation, Thesis Writing, Viva Voce Preparation |
| DE-V | Departmental Elective-V | Elective | 8.5 | Additive Manufacturing, Nuclear Materials, Biomaterials and Implants, Superalloys, Friction Stir Welding |
| MM7xx | Departmental Core (M.Tech)-II | Core | 9 | Advanced Mechanical Behavior, Structure-Property Relationships, Nanostructured Materials, Surface Engineering, Material Selection and Design |
| DE-M.Tech-I | Departmental Elective (M.Tech)-I | Elective | 9 | Advanced Alloy Design, High Temperature Materials, Computational Materials Science, Advanced Characterization, Functional Coatings |
Semester 9
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| MM801 | Thesis (Phase I) | Project | 18 | Research Proposal Development, Extensive Literature Review, Initial Experimental/Computational Work, Methodology Refinement, Progress Reporting |
| DE-M.Tech-II | Departmental Elective (M.Tech)-II | Elective | 9 | Materials for Biomedical Applications, Energy Storage Materials, Materials for Extreme Environments, Advanced Powder Metallurgy, Smart Materials |
Semester 10
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| MM802 | Thesis (Phase II) | Project | 27 | Advanced Research Execution, Data Interpretation and Discussion, Comprehensive Thesis Writing, Final Presentation and Defense, Publication Preparation |
