Materials Science & Engineering Course | IIT Roorkee | Prof. Vivek Pancholi
Course Details
| Exam Registration | 280 |
|---|---|
| Course Status | Ongoing |
| Course Type | Elective |
| Language | English |
| Duration | 8 weeks |
| Categories | Metallurgy and Material science & Mining Engineering |
| Credit Points | 2 |
| Level | Undergraduate |
| Start Date | 19 Jan 2026 |
| End Date | 13 Mar 2026 |
| Enrollment Ends | 02 Feb 2026 |
| Exam Registration Ends | 16 Feb 2026 |
| Exam Date | 28 Mar 2026 IST |
| NCrF Level | 4.5 — 8.0 |
Unlock the World of Materials: A Comprehensive Guide to IIT Roorkee's Premier Course
In the realm of engineering, the foundation of every innovation—from sleek smartphones to robust bridges—lies in the materials used. Understanding the science behind these materials is crucial for any aspiring engineer. This is where the Materials Science and Engineering course, offered by the prestigious Indian Institute of Technology (IIT) Roorkee and taught by the esteemed Prof. Vivek Pancholi, becomes an invaluable resource. This detailed 8-week undergraduate program is meticulously designed to transform your understanding of structural materials.
Meet Your Expert Instructor: Prof. Vivek Pancholi
Learning from an expert with both deep academic knowledge and practical teaching experience is paramount. Prof. Vivek Pancholi brings over a decade of dedicated teaching experience at IIT Roorkee to this course.
- Academic Pedigree: Holds a PhD in Metallurgical Engineering from IIT Bombay, an M.Tech. from IIT Delhi, and a BE from G.S.I.T.S. Indore.
- Teaching Expertise: Has taught core undergraduate courses including Structural Metallurgy, Phase Transformation, Welding & Casting, and Mechanical Behavior of Materials.
- Research Leadership: A prolific researcher with over 35 publications in top journals and guidance for multiple PhD scholars, backed by 05 sponsored research projects.
His blend of theoretical mastery and practical insight ensures the course content is both rigorous and highly applicable.
Who Should Enroll in This Course?
This course is strategically crafted to serve a specific audience, ensuring focused and relevant learning.
- Primary Audience: Undergraduate students (BE/B.Tech) in Mechanical and Production Engineering.
- Extended Audience: Students from Metallurgy, Materials Science, and Mining Engineering backgrounds.
- Industry Professionals: Practicing engineers in manufacturing, automobile, and auto-ancillary industries seeking to solidify or refresh their core knowledge.
The course enjoys strong industry support from major manufacturing and automotive sectors, underscoring its practical relevance.
Course Overview: Bridging Theory and Practice
Structured over 8 weeks, the course is divided into three fundamental pillars of materials engineering, ensuring a holistic learning journey from atomic structures to real-world applications.
Detailed 8-Week Course Layout
| Week | Core Topics Covered |
|---|---|
| Week 1 | Lattice, Crystal Structures, Miller Indices for planes and directions. |
| Week 2 | Microscopes, Microstructures, Quantitative Metallography. |
| Week 3 | Crystal Defects, Diffusion, Introduction to Phase Diagrams. |
| Week 4 | Equilibrium Phase Diagrams, Lever Rule, Phase Transformations. |
| Week 5 | Iron-Carbon Phase Diagram, TTT & CCT Curves, Heat Treatments. |
| Week 6 | Introduction to Mechanical Properties, Cold and Hot Working. |
| Week 7 | Strengthening Mechanisms, Fracture, and Fatigue. |
| Week 8 | Creep, Ceramics & Plastics, NDT Techniques, Alloy Designation. |
Deep Dive into the Three Pillars of the Course
1. Crystallography and Crystal Defects
This module forms the bedrock of materials science. You will start at the atomic level, learning about different crystal systems and structures. You'll master the skill of indexing planes and directions using Miller Indices. The section then explores imperfections—like vacancies, dislocations, and grain boundaries—that critically influence material properties, linking them directly to observable microstructures.
2. Phase Diagrams and Heat Treatment
Here, you'll learn the roadmap for understanding material composition and processing. Starting with the Gibbs Phase Rule, the course progresses to binary phase diagrams and invariant reactions. The pivotal Iron-Carbon phase diagram is covered in depth, along with Time-Temperature-Transformation (TTT) and Continuous-Cooling-Transformation (CCT) curves. This knowledge directly applies to various heat treatment processes used to tailor material properties like hardness and toughness.
3. Mechanical Properties
This pillar connects structure to performance. You will distinguish between elastic and plastic deformation, understand engineering vs. true stress-strain curves, and define key properties like tensile strength, ductility, and toughness. The course explains forming processes (cold/hot working) and crucial strengthening mechanisms. It concludes with failure analysis, covering fracture, fatigue, and creep, alongside an introduction to non-destructive testing (NDT) techniques.
Essential Learning Resources
To complement the video lectures, the course recommends two classic textbooks that are cornerstones in the field:
- Callister's Materials Science and Engineering: An Introduction – A globally acclaimed text known for its clarity and comprehensive coverage.
- Raghavan's Materials Science and Engineering: A First Course – A highly regarded book offering a strong conceptual foundation.
Why This Course is a Must for Your Engineering Career
Enrolling in this course offers a structured path to mastering the principles that dictate why materials behave the way they do. Whether you aim to excel in academics, innovate in R&D, or solve practical problems on the manufacturing floor, the knowledge gained here—from the atomic arrangement in a crystal to selecting the right heat treatment for a steel component—is indispensable. Under the guidance of Prof. Pancholi, you're not just learning concepts; you're gaining the tools to engineer the future.
Enroll Now →