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B-TECH-M-TECH in Industrial Ceramics Ceramic Engineering at National Institute of Technology Rourkela
Sundargarh, Odisha
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About the Specialization
What is Industrial Ceramics & Ceramic Engineering at National Institute of Technology Rourkela Sundargarh?
This Industrial Ceramics & Ceramic Engineering program at NIT Rourkela focuses on the science and engineering of ceramic materials, from raw material processing to advanced product design and manufacturing. It''''s crucial for various Indian industries including automotive, defense, electronics, and infrastructure, where high-performance, heat-resistant, and durable materials are in high demand. The program emphasizes both fundamental scientific principles and practical industrial applications, preparing students for the evolving needs of the Indian materials sector.
Who Should Apply?
This program is ideal for ambitious 10+2 graduates with a strong foundation in Physics, Chemistry, and Mathematics who possess an aptitude for materials science and engineering. It''''s also suitable for B.Tech graduates in related fields seeking advanced specialization, and young professionals aiming to enter or advance in the ceramic and advanced materials manufacturing industries in India. A keen interest in research, innovation, and industrial processes is highly beneficial for prospective students.
Why Choose This Course?
Graduates of this program can expect diverse and rewarding career paths in India''''s growing industrial landscape, including roles in R&D, manufacturing, quality control, and process engineering across sectors like defense, aerospace, electronics, and traditional ceramics. Entry-level salaries typically range from INR 6-10 LPA, growing significantly with experience. Opportunities also exist in materials characterization, product development, and academic research, contributing to India''''s ''''Make in India'''' and self-reliance initiatives in advanced materials.
Student Success Practices
Foundation Stage
Build a Strong STEM Foundation- (Semester 1-2)
Focus intently on mastering core engineering mathematics, physics, and chemistry. Utilize online platforms like NPTEL for supplemental learning and practice problem-solving rigorously. Form study groups with peers to clarify concepts and tackle challenging problems collaboratively.
Tools & Resources
NPTEL courses, Khan Academy, Local coaching institutes for competitive exams, Peer study groups
Career Connection
A solid foundation in basic sciences and engineering is crucial for understanding advanced ceramic engineering concepts, which directly impacts project execution and problem-solving abilities in industrial settings, leading to better internship and placement opportunities.
Develop Programming and CAD Skills- (Semester 1-3)
Engage actively in computer programming labs and consider taking introductory CAD courses or certifications. Practice coding logic using platforms like HackerRank and familiarize yourself with engineering design software such as AutoCAD or SolidWorks (student versions).
Tools & Resources
CodeChef, GeeksforGeeks, SolidWorks Student Edition, AutoCAD tutorials, Departmental computing facilities
Career Connection
Proficiency in programming and CAD is increasingly vital for materials engineers for data analysis, process simulation, and ceramic component design, making graduates highly valuable for R&D and manufacturing roles in modern industries.
Cultivate Effective Communication Skills- (Semester 1-2)
Actively participate in English for Communication classes, join debate clubs, or take on roles that require public speaking and report writing. Seek feedback on your writing and presentation skills from professors and peers.
Tools & Resources
Toastmasters International (if available nearby), University communication workshops, Online grammar and writing tools, Peer feedback sessions
Career Connection
Strong communication skills are essential for presenting technical reports, collaborating in teams, and client interactions, directly impacting leadership potential and professional growth in any engineering role.
Intermediate Stage
Engage in Departmental Projects & Workshops- (Semester 3-5)
Proactively seek out opportunities to work on minor research projects with faculty members within the Ceramic Engineering department. Attend specialized workshops on ceramic processing, characterization, or advanced materials to gain hands-on experience and network with experts.
Tools & Resources
Departmental research labs, Faculty mentors, NIT Rourkela''''s student research forums, Industry-sponsored workshops
Career Connection
Early research exposure and practical skills gained from projects enhance your resume for internships and demonstrate your practical application abilities, critical for R&D and process engineering roles.
Seek Industrial Internships & Site Visits- (Semester 4-6 summer breaks)
Actively apply for summer internships in ceramic manufacturing units, refractories, glass industries, or materials R&D centers across India. Even short-term industrial visits can provide invaluable insights into real-world applications and processes.
Tools & Resources
NIT Rourkela Placement Cell, Internshala, Company websites (Tata Steel, CUMI, SAIL, DRDO), Alumni network
Career Connection
Internships bridge the gap between academic learning and industrial practice, often leading to pre-placement offers (PPOs) and providing a competitive edge for final placements in core ceramic industries.
Participate in Technical Competitions & Societies- (Semester 3-6)
Join relevant technical societies (e.g., student chapters of Indian Ceramic Society) and participate in national-level technical paper presentations, design competitions, or materials science challenges. This builds problem-solving skills and a professional network.
Tools & Resources
Indian Ceramic Society student chapter, MRS India chapter, Inter-college technical festivals, Departmental clubs
Career Connection
Participation in competitions hones critical thinking, teamwork, and presentation skills, making you a well-rounded candidate sought after by companies looking for innovative and adaptable engineers.
Advanced Stage
Deep Dive into Dual Degree Project/Thesis- (Semester 7-10)
Treat your B.Tech and M.Tech projects as significant research endeavors. Choose a topic aligned with industrial demand or cutting-edge research in industrial ceramics. Dedicate ample time to literature review, experimental work, data analysis, and scientific writing, aiming for publication if possible.
Tools & Resources
Scopus, Web of Science, Departmental research facilities, Statistical software (MATLAB, Origin), Faculty advisors
Career Connection
A strong dual degree thesis demonstrates advanced research capabilities and specialized knowledge, making you a prime candidate for R&D positions, higher studies (PhD), or leadership roles requiring innovative problem-solving in industrial ceramic companies.
Master Advanced Characterization & Simulation Tools- (Semester 7-9)
Gain proficiency in advanced materials characterization techniques (SEM, XRD, TEM) and computational tools (Finite Element Analysis for ceramic design, thermodynamic software). Seek certification if available or volunteer for lab assistant roles to gain hands-on experience.
Tools & Resources
Advanced instrumentation labs, Ansys, COMSOL Multiphysics, Thermo-Calc, Online certification courses
Career Connection
Expertise in these tools is highly valued in modern ceramic industries for quality control, process optimization, and new product development, directly enhancing your employability in advanced engineering and research roles.
Network and Prepare for Placements/Higher Studies- (Semester 8-10)
Actively network with alumni, industry professionals, and recruiters through LinkedIn and career fairs. Refine your resume, practice technical interviews, and prepare for competitive exams (GATE, GRE) if considering higher studies or public sector opportunities.
Tools & Resources
LinkedIn, NIT Rourkela Alumni Network, Placement Cell workshops, Mock interview sessions, GATE/GRE preparation platforms
Career Connection
Proactive networking and thorough preparation significantly increase your chances of securing placements in top companies or gaining admission to prestigious PhD programs, shaping your long-term career trajectory.
Program Structure and Curriculum
Eligibility:
- 10+2 with Physics, Chemistry, Mathematics (PCM) with minimum aggregate marks (typically 75% or top 20 percentile in board exams) and a valid JEE Main rank, followed by JoSAA/CSAB counselling.
Duration: 10 Semesters / 5 Years
Credits: 212-220 (approximate, based on typical NIT Dual Degree structure and subject credits) Credits
Assessment: Internal: 30-50%, External: 50-70%
Semester-wise Curriculum Table
Semester 1
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| MA1001 | Mathematics - I | Core | 4 | Differential Calculus, Integral Calculus, Sequences and Series, Vector Calculus, Matrices and Determinants |
| PH1001 | Physics - I (Mechanics, Optics & Modern Physics) | Core | 4 | Classical Mechanics, Wave Optics, Quantum Mechanics Introduction, Special Relativity, Atomic and Nuclear Physics |
| CH1001 | Chemistry - I | Core | 4 | Atomic Structure & Bonding, Thermodynamics & Kinetics, Electrochemistry, Spectroscopy, Organic Chemistry Basics |
| CE1001 | Engineering Graphics | Core | 3 | Projection of Points, Lines, Planes, Projection of Solids, Section of Solids, Development of Surfaces, Isometric Projections |
| LA1001 | English for Communication | Core | 2 | Grammar & Usage, Effective Writing, Reading Comprehension, Oral Communication, Presentation Skills |
| PH1071 | Physics Lab - I | Lab | 1 | Error Analysis, Simple Pendulum, Young''''s Modulus, Diffraction Grating, PN Junction Diode Characteristics |
| CH1071 | Chemistry Lab - I | Lab | 1 | Volumetric Analysis, pH Metry, Conductometry, Spectrophotometry, Preparation of Organic Compounds |
Semester 2
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| MA1002 | Mathematics - II | Core | 4 | Ordinary Differential Equations, Partial Differential Equations, Laplace Transforms, Fourier Series, Complex Analysis |
| EE1001 | Basic Electrical Engineering | Core | 4 | DC Circuits, AC Circuits, Transformers, DC Machines, AC Machines |
| CS1001 | Computer Programming | Core | 3 | Introduction to C/C++, Data Types & Operators, Control Structures, Functions & Arrays, Pointers & Structures |
| ME1001 | Engineering Mechanics | Core | 3 | Forces & Equilibrium, Friction, Centroid & Moment of Inertia, Kinematics of Particles, Kinetics of Particles |
| EC1001 | Basic Electronics Engineering | Core | 4 | Semiconductor Diodes, Bipolar Junction Transistors, Field Effect Transistors, Operational Amplifiers, Digital Logic Gates |
| CS1071 | Computer Programming Lab | Lab | 1 | C/C++ Programming Exercises, Conditional Statements, Looping Constructs, Functions Implementation, Array and String Manipulation |
| ME1071 | Workshop Practice | Lab | 1 | Fitting, Welding, Carpentry, Foundry, Machine Shop |
Semester 3
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| MA2001 | Engineering Mathematics - III | Core | 4 | Probability Theory, Random Variables, Statistical Distributions, Hypothesis Testing, Regression Analysis |
| CR2001 | Fundamentals of Ceramic Engineering | Core | 3 | Introduction to Ceramics, Classification of Ceramics, Atomic Bonding & Crystal Structure, Defects in Crystalline Solids, Basic Properties of Ceramics |
| CR2003 | Material Science & Engineering | Core | 4 | Bonding and Crystal Structures, Phase Diagrams, Mechanical Properties of Materials, Electrical Properties of Materials, Thermal Properties of Materials |
| CR2005 | Chemical Thermodynamics | Core | 3 | First Law of Thermodynamics, Second Law of Thermodynamics, Gibbs Free Energy, Phase Rule, Thermodynamics of Solutions |
| CR2007 | Strength of Materials | Core | 3 | Stress and Strain, Axial Loading, Torsion, Bending, Shear and Moment Diagrams |
| CR2071 | Ceramic Materials Lab - I | Lab | 2 | Density Measurement, Porosity Measurement, Particle Size Analysis, Strength Testing, Hardness Testing |
Semester 4
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| CR2002 | Heat and Mass Transfer | Core | 4 | Conduction, Convection, Radiation, Heat Exchangers, Diffusion Mass Transfer, Convective Mass Transfer, Interphase Mass Transfer |
| CR2004 | Mechanical Operations | Core | 3 | Size Reduction, Size Enlargement, Solid-Fluid Separation, Fluidization, Mixing of Solids |
| CR2006 | Phase Equilibria in Ceramic Systems | Core | 3 | Phase Rule Application, Binary Phase Diagrams, Ternary Phase Diagrams, Eutectic, Peritectic Reactions, Solid Solutions |
| CR2008 | Fluid Mechanics | Core | 3 | Fluid Properties, Fluid Statics, Fluid Dynamics, Flow Through Pipes, Boundary Layer Theory |
| CR2010 | Numerical Methods in Engineering | Core | 3 | Roots of Equations, Interpolation, Numerical Differentiation, Numerical Integration, Solution of ODEs |
| CR2072 | Ceramic Processing Lab - I | Lab | 2 | Powder Preparation, Slip Casting, Extrusion, Pressing, Sintering Basics |
Semester 5
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| CR3001 | Refractories | Core | 3 | Classification of Refractories, Raw Materials, Manufacturing Processes, Properties and Applications, Testing of Refractories |
| CR3003 | Glass Technology | Core | 3 | Glass Structure, Glass Forming Oxides, Glass Manufacturing, Properties of Glass, Applications of Glass |
| CR3005 | Advanced Ceramics | Core | 3 | Engineering Ceramics, Electronic Ceramics, Bioceramics, Optical Ceramics, Ceramic Matrix Composites |
| CR3007 | Ceramic Rheology | Core | 3 | Viscosity, Non-Newtonian Fluids, Rheological Models, Suspension Rheology, Measurement Techniques |
| OE3XXX | Open Elective - I | Elective | 3 | |
| CR3071 | Material Characterization Lab | Lab | 2 | XRD Analysis, SEM & EDS, Thermal Analysis (DTA/TGA), FTIR Spectroscopy, Optical Microscopy |
Semester 6
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| CR3002 | Structural Ceramics | Core | 3 | Ceramic Toughness, Strength and Reliability, Fatigue and Creep, Fracture Mechanics, Applications in High Temperature |
| CR3004 | Ceramic Design and Application | Core | 3 | Design Principles, Material Selection, Component Design, Failure Analysis, Case Studies |
| CR3006 | Bioceramics | Departmental Elective | 3 | Biocompatibility, Bioactive Ceramics, Implants, Tissue Engineering, Drug Delivery Systems |
| CR3XXX | Departmental Elective - I | Elective | 3 | |
| OE3XXX | Open Elective - II | Elective | 3 | |
| CR3072 | Ceramic Testing Lab | Lab | 2 | Mechanical Testing, Thermal Shock Resistance, Electrical Property Measurement, Chemical Durability, Creep Measurement |
| IN3001 | Industrial Training / Internship | Audit/Project | 2 | Industrial Exposure, Project Implementation, Report Writing, Presentation Skills |
Semester 7
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| CR4001 | Powder Metallurgy | Core | 3 | Powder Production, Powder Characterization, Compaction Techniques, Sintering, Post-sintering Operations |
| CR4003 | Sintering Theory and Practice | Core | 3 | Driving Forces for Sintering, Sintering Mechanisms, Liquid Phase Sintering, Pressure Assisted Sintering, Sintering Defects |
| CR4005 | Advanced Characterization Techniques | Core | 3 | Electron Microscopy (TEM, SEM), Spectroscopy (XPS, AES), Diffraction Techniques (Neutron, Synchrotron), Surface Analysis, Microscopy Techniques |
| CR4XXX | Departmental Elective - II | Elective | 3 | |
| OE4XXX | Open Elective - III | Elective | 3 | |
| CR4091 | B.Tech Project / Seminar - I | Project | 4 | Literature Review, Problem Formulation, Methodology Design, Preliminary Data Collection |
Semester 8
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| CR4002 | Ceramic Composites | Core | 3 | Classification of Composites, Fibers and Whiskers, Matrix Materials, Processing of Composites, Properties and Applications |
| CR4004 | Ceramic Coatings and Thin Films | Core | 3 | Deposition Techniques, Characterization of Coatings, Properties of Coatings, Applications in Wear & Corrosion, Optical & Electronic Coatings |
| CR4XXX | Departmental Elective - III | Elective | 3 | |
| CR4XXX | Departmental Elective - IV | Elective | 3 | |
| CR4092 | B.Tech Project / Seminar - II | Project | 6 | Experimental Work, Data Analysis, Results and Discussion, Thesis Writing, Final Presentation |
Semester 9
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| IC5001 | Advanced Industrial Ceramics | Core | 4 | High Performance Ceramics, Ceramic Processing Technologies, Quality Control in Ceramic Industry, Failure Analysis, Specialized Ceramic Applications |
| IC5003 | Ceramic Forming Techniques | Core | 4 | Powder Processing, Colloidal Processing, Green Body Fabrication, Advanced Sintering Methods, Additive Manufacturing of Ceramics |
| IC5XXX | M.Tech Elective - I | Elective | 3 | |
| IC5091 | M.Tech Project / Thesis Part - I | Project | 8 | Detailed Literature Survey, Research Proposal Development, Experimental Setup Design, Initial Data Collection, Progress Report |
Semester 10
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| IC5002 | Manufacturing & Quality Control of Ceramics | Core | 4 | Industrial Ceramic Manufacturing, Process Optimization, Statistical Quality Control, Product Standards and Certification, Lean Manufacturing Principles |
| IC5XXX | M.Tech Elective - II | Elective | 3 | |
| IC5XXX | M.Tech Elective - III | Elective | 3 | |
| IC5092 | M.Tech Project / Thesis Part - II | Project | 14 | Advanced Experimental Work, Comprehensive Data Analysis, Thesis Writing and Defense, Publication Preparation, Innovation and Industrial Relevance |
