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B-TECH-MBA in Metallurgical Materials Engineering at Kalinga Institute of Industrial Technology
Khordha, Odisha
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About the Specialization
What is Metallurgical & Materials Engineering at Kalinga Institute of Industrial Technology Khordha?
This Metallurgical & Materials Engineering program at Kalinga Institute of Industrial Technology, Bhubaneswar focuses on the science and engineering of metals, alloys, ceramics, polymers, and composites. It covers the extraction, processing, characterization, and application of materials critical for various industries. India''''s rapidly expanding manufacturing, automotive, aerospace, and energy sectors drive a significant demand for skilled metallurgical and materials engineers, making this program highly relevant to national industrial growth and technological advancement.
Who Should Apply?
This program is ideal for high school graduates with a strong aptitude in Physics, Chemistry, and Mathematics, eager to understand the fundamental properties and applications of materials. It also suits those aspiring to contribute to India''''s burgeoning R&D landscape in materials science, or for students aiming for advanced studies in specialized fields like nanotechnology or biomaterials. Freshers seeking a robust engineering foundation coupled with management skills for industrial leadership are also well-suited.
Why Choose This Course?
Graduates of this program can expect diverse career paths in core industries such as steel, non-ferrous metals, automotive, aerospace, and electronics in India. Roles include process engineer, materials scientist, quality control engineer, and R&D specialist. Entry-level salaries typically range from INR 4-7 LPA, with experienced professionals earning INR 10-25 LPA or more. The dual degree enhances managerial capabilities, opening doors to leadership and techno-commercial roles in major Indian corporations and MNCs.
Student Success Practices
Foundation Stage
Build Strong Engineering & Science Fundamentals- (Semester 1-2)
Focus on mastering core concepts in Mathematics, Physics, Chemistry, and Basic Engineering. Regularly solve problems from textbooks and online resources. Form study groups to discuss complex topics and clarify doubts, reinforcing conceptual understanding.
Tools & Resources
NPTEL lectures, Khan Academy, Specific engineering textbooks, Departmental problem-solving sessions, Peer tutoring
Career Connection
A solid foundation is crucial for understanding advanced materials concepts and cracking technical interviews for core engineering roles and competitive exams.
Develop Foundational Programming & Design Skills- (Semester 1-2)
Actively engage in programming labs, practicing C/C++ to build problem-solving logic. Simultaneously, master engineering graphics and design software basics to visualize material structures and processes. Participate in coding competitions or design challenges for practical application.
Tools & Resources
HackerRank, GeeksforGeeks, AutoCAD/SolidWorks tutorials, University''''s CAD labs, Coding platforms
Career Connection
Programming skills are increasingly vital for materials data analysis, simulation, and automation, while design skills are key for product development and process layout in industries.
Cultivate Effective Communication & Professional Etiquette- (Semester 1-2)
Leverage English Communication and Environmental Science courses to hone presentation and report writing skills. Practice active listening and public speaking. Attend workshops on soft skills, focusing on interview preparation and professional conduct essential for the workplace.
Tools & Resources
University communication labs, Toastmasters International clubs (if available), Online courses on professional etiquette, LinkedIn Learning modules
Career Connection
Strong communication is essential for effective teamwork, client interaction, and successful placements in any industry role, especially in techno-managerial positions.
Intermediate Stage
Engage in Materials Characterization & Testing- (Semester 3-5)
Maximize learning from Materials Testing & Characterization and Physical Metallurgy labs. Actively operate equipment like microscopes, tensile testers, and XRD. Document observations meticulously and correlate them with theoretical concepts. Seek opportunities to assist faculty in lab projects.
Tools & Resources
Lab manuals, Research papers, Specialized software for data analysis (e.g., ImageJ), Departmental advanced instrumentation
Career Connection
Hands-on experience in material testing and characterization is highly valued by R&D labs, quality control departments, and manufacturing industries in India.
Seek Industry Internships and Live Projects- (Semester 4-5)
Actively apply for summer internships at steel plants, automotive manufacturers, materials R&D centers (e.g., DRDO, NML). Even short-term industrial visits or participation in live projects offered by the department can provide invaluable exposure to real-world metallurgical challenges.
Tools & Resources
KIIT''''s Training & Placement Cell, LinkedIn for networking, Industry contacts and alumni network, Company career portals
Career Connection
Internships bridge the gap between academic knowledge and industry demands, often leading to pre-placement offers and a strong resume for placements in core sectors.
Build a Strong Network & Participate in Technical Competitions- (Semester 3-5)
Attend webinars, seminars, and conferences related to materials science. Join student chapters of professional bodies like IIM (Indian Institute of Metals). Participate in national-level technical paper presentations, quiz competitions, or design challenges in metallurgy and materials.
Tools & Resources
IIM student chapter events, Online platforms for webinars (e.g., YouTube channels of research institutes), College technical fests, LinkedIn for professional networking
Career Connection
Networking opens doors to mentorship and job opportunities, while competition participation showcases problem-solving skills and enhances visibility to potential employers.
Advanced Stage
Deep Dive into Major Project Work & Research- (Semester 6-8)
Dedicate significant effort to the Minor and Major Projects. Identify a research area of interest, conduct thorough literature reviews, design experiments, analyze data rigorously, and present findings effectively. Aim for publication in a conference or journal.
Tools & Resources
University research labs, Faculty mentors for guidance, Scientific databases (Scopus, Web of Science), LaTeX/Word for report writing, presentation software
Career Connection
A strong project demonstrates research capabilities, independent problem-solving, and contributes significantly to a compelling portfolio for R&D roles, higher studies, and technical interviews.
Prepare Strategically for Placements & MBA Aptitude- (Semester 7-8)
Begin rigorous preparation for placement tests (aptitude, technical, verbal) and group discussions/interviews. Simultaneously, for the MBA component, prepare for CAT/XAT/KIITEE Management exams, focusing on quantitative ability, logical reasoning, and verbal comprehension.
Tools & Resources
Online aptitude platforms (e.g., Indiabix, M4 Maths), Coaching institutes for competitive exams, Mock interviews and group discussions, Previous year papers for entrance exams, KIIT''''s Career Development Cell
Career Connection
Targeted preparation for both engineering placements and MBA entrance exams maximizes opportunities for desired career paths and secures admission into the MBA part of the dual degree.
Specialize through Electives and Advanced Workshops- (Semester 7-8)
Carefully choose program and open electives aligned with career aspirations (e.g., Additive Manufacturing, Nanomaterials, Biomaterials). Attend advanced workshops or certification courses in emerging areas of materials technology to gain specialized skills and stay updated with industry trends.
Tools & Resources
Departmental elective offerings, Online certification platforms (Coursera, edX), Industry-specific short courses, Specialized software training in simulation or design
Career Connection
Specialization makes graduates highly competitive for niche roles in advanced manufacturing, materials R&D, and positions requiring specific technical expertise in the rapidly evolving materials landscape.
Program Structure and Curriculum
Eligibility:
- Passed 10+2 or equivalent examination in 2022, 2023 or appearing in 2024 with at least 60% marks in Physics, Chemistry and Mathematics (PCM) taken together. Candidates must have a good rank in KIITEE 2024.
Duration: 8 semesters for B.Tech component (typically 10 semesters for B.Tech + MBA dual degree)
Credits: 160 (for B.Tech component) Credits
Assessment: Internal: 30%, External: 70%
Semester-wise Curriculum Table
Semester 1
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| BS1001 | Mathematics-I | Core | 4 | Differential Calculus, Integral Calculus, Sequences and series, Multivariable calculus, Vector calculus |
| CH1001 | Chemistry | Core | 3 | Atomic structure and bonding, Chemical thermodynamics, Electrochemistry, Reaction kinetics, Engineering materials |
| ES1001 | Basic Electrical Engineering | Core | 3 | DC circuits, AC circuits, Transformers, DC machines, Induction motors |
| CS1001 | Programming for Problem Solving | Core | 3 | C programming basics, Control flow, Functions, Arrays, Pointers, Structures |
| HS1001 | English Communication | Core | 2 | Communication skills, Grammar and vocabulary, Reading comprehension, Report writing, Presentation skills |
| CH1002 | Chemistry Lab | Lab | 1 | Volumetric analysis, Chemical kinetics, Electrochemistry experiments, Water analysis |
| ES1002 | Basic Electrical Engineering Lab | Lab | 1 | DC and AC circuit experiments, Electrical machine characteristics, Measurement techniques |
| CS1002 | Programming for Problem Solving Lab | Lab | 1 | C programming exercises, Debugging techniques, Basic algorithm implementation |
Semester 2
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| BS1002 | Mathematics-II | Core | 4 | Differential equations, Laplace transforms, Fourier series, Complex analysis, Probability and statistics |
| PH1001 | Physics | Core | 3 | Wave optics, Quantum mechanics, Lasers, Optical fibers, Solid state physics |
| ME1001 | Engineering Graphics & Design | Core | 2 | Projections, Orthographic drawings, Sectional views, Isometric views, CAD basics |
| HS1002 | Environmental Science | Core | 2 | Ecosystems and biodiversity, Pollution control, Waste management, Environmental ethics, Sustainable development |
| ME1002 | Engineering Workshop / Manufacturing Practices | Lab | 2 | Carpentry, Fitting, Welding, Machining, Foundry operations |
| EC1001 | Basic Electronics Engineering | Core | 3 | Semiconductor devices, Diode circuits, Transistor circuits, Operational amplifiers, Digital electronics |
| EC1002 | Basic Electronics Engineering Lab | Lab | 1 | Diode and transistor characteristics, Rectifier circuits, Amplifier designs, Logic gate experiments |
| PH1002 | Physics Lab | Lab | 1 | Optics experiments, Semiconductor physics studies, Magnetic field measurements |
Semester 3
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| BS2001 | Mathematics-III | Core | 4 | Numerical methods, Linear algebra, Probability distributions, Stochastic processes, Optimization techniques |
| MT2001 | Principles of Physical Metallurgy | Core | 3 | Crystalline structures, Imperfections in solids, Diffusion mechanisms, Phase diagrams, Heat treatment processes |
| MT2002 | Thermodynamics of Materials | Core | 3 | First and second laws of thermodynamics, Free energy concepts, Chemical potential, Phase equilibria, Solutions and mixtures |
| MT2003 | Materials Testing & Characterization | Core | 3 | Mechanical testing methods, Non-destructive testing, Optical microscopy, Electron microscopy, X-ray diffraction |
| HS2001 | Professional Ethics & Human Values | Core | 2 | Ethical theories, Professional responsibility, Corporate ethics, Environmental ethics, Human rights |
| MT2004 | Physical Metallurgy Lab | Lab | 1 | Microstructure examination, Heat treatment experiments, Hardness testing, Grain size determination |
| MT2005 | Materials Characterization Lab | Lab | 1 | Tensile testing, Impact testing, Optical microscopy techniques, Specimen preparation |
| OE2XXX | Open Elective-I | Elective | 3 |
Semester 4
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| MT2006 | Extractive Metallurgy | Core | 3 | Mineral beneficiation, Pyrometallurgy principles, Hydrometallurgy processes, Electrometallurgy techniques, Process economics |
| MT2007 | Mechanical Behavior of Materials | Core | 3 | Elasticity and plasticity, Creep and fatigue, Fracture mechanics, Strengthening mechanisms, Deformation processes |
| MT2008 | Foundry & Welding Technology | Core | 3 | Sand casting, Die casting, Arc welding, Resistance welding, Brazing and soldering, Solidification processes |
| MT2009 | Materials Science & Engineering | Core | 3 | Structure-property correlation, Ceramics and glasses, Polymers and plastics, Composites, Advanced materials |
| HS2002 | Organizational Behavior / Principles of Management | Core | 3 | Management functions, Organizational structure, Motivation theories, Leadership styles, Team dynamics |
| MT2010 | Extractive Metallurgy Lab | Lab | 1 | Ore preparation, Leaching experiments, Smelting simulation, Electrolysis studies |
| MT2011 | Foundry & Welding Lab | Lab | 1 | Casting practices, Welding techniques, Defect analysis, Metallography of welds |
| OE2XXX | Open Elective-II | Elective | 3 |
Semester 5
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| MT3001 | Phase Transformations | Core | 3 | Nucleation and growth, Diffusion transformations, Martensitic transformations, Precipitation hardening, Spinodal decomposition |
| MT3002 | Powder Metallurgy | Core | 3 | Powder production methods, Compaction processes, Sintering mechanisms, Hot isostatic pressing, Applications of powder metallurgy |
| MT3003 | Corrosion and Degradation of Materials | Core | 3 | Electrochemical corrosion, Forms of corrosion, Oxidation mechanisms, Corrosion control strategies, Material selection for corrosion resistance |
| MT3004 | Non-Ferrous Extractive Metallurgy | Core | 3 | Extraction of Aluminum, Extraction of Copper, Extraction of Zinc, Extraction of Lead, Extraction of Magnesium and Titanium |
| PE3XXX | Program Elective-I | Elective | 3 | |
| MT3005 | Powder Metallurgy Lab | Lab | 1 | Powder characterization, Compaction experiments, Sintering studies, Density measurements |
| MT3006 | Corrosion and Failure Analysis Lab | Lab | 1 | Corrosion rate measurement, Potentiodynamic polarization, Failure mode identification, Microscopic examination of failures |
| OE3XXX | Open Elective-III | Elective | 3 |
Semester 6
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| MT3007 | Manufacturing of Materials | Core | 3 | Bulk deformation processes, Sheet metal forming, Machining processes, Joining processes, Additive manufacturing |
| MT3008 | Surface Engineering | Core | 3 | Surface properties, Coating processes, Thermal spraying, Physical Vapor Deposition (PVD), Chemical Vapor Deposition (CVD) |
| MT3009 | Mechanical Working of Metals | Core | 3 | Forging operations, Rolling processes, Extrusion techniques, Drawing processes, Defects in worked products |
| PE3XXX | Program Elective-II | Elective | 3 | |
| PE3XXX | Program Elective-III | Elective | 3 | |
| MT3010 | Manufacturing of Materials Lab | Lab | 1 | Forming experiments, Machining operations, Sheet metal work, Joining techniques |
| MT3011 | Mechanical Working Lab | Lab | 1 | Rolling experiments, Forging practices, Extrusion principles, Drawing demonstrations |
| PROJ3001 | Minor Project | Project | 2 | Project formulation, Literature review, Experimental design, Data analysis, Report writing and presentation |
Semester 7
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| MT4001 | Quality Control & Assurance in Materials | Core | 3 | Statistical process control (SPC), Quality management systems (QMS), Non-destructive testing (NDT), Process capability analysis, Material certification |
| MT4002 | Iron & Steel Making | Core | 3 | Blast furnace technology, Basic Oxygen Furnace (BOF), Electric Arc Furnace (EAF), Secondary refining processes, Continuous casting |
| PE4XXX | Program Elective-IV | Elective | 3 | |
| PE4XXX | Program Elective-V | Elective | 3 | |
| MT4003 | Seminar | Project | 1 | Research methodology, Technical presentation skills, Literature review, Critical analysis |
| MT4004 | Industrial Training | Project | 1 | Industrial exposure, Practical application of engineering principles, Report on training experience, Observation and analysis of industrial processes |
| PROJ4001 | Major Project-I | Project | 3 | Advanced project design, Methodology development, Preliminary experimental results, Interim report writing, Problem identification and scope definition |
| HS4001 | Managerial Economics / Financial Management | Core | 3 | Demand and supply analysis, Market structures, Cost analysis, Investment decisions, Capital budgeting |
Semester 8
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| PE4XXX | Program Elective-VI | Elective | 3 | |
| PE4XXX | Program Elective-VII | Elective | 3 | |
| PROJ4002 | Major Project-II | Project | 6 | Advanced research and development, Experimental validation, Comprehensive report submission, Thesis defense, Innovation and problem solving |
| HS4002 | Entrepreneurship Development | Core | 3 | Entrepreneurial mindset, Business plan development, Startup ecosystem in India, Funding sources, Marketing for startups |
| HS4003 | Legal and Business Environment | Core | 3 | Business law fundamentals, Contract law, Intellectual property rights, Regulatory compliance, Corporate governance |
| OE4XXX | Open Elective-IV | Elective | 3 |
