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MASTER-OF-TECHNOLOGY in Thermal Science Mechanical at North-Eastern Regional Institute of Science and Technology
Papum Pare, Arunachal Pradesh
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About the Specialization
What is Thermal Science (Mechanical) at North-Eastern Regional Institute of Science and Technology Papum Pare?
This Thermal Science (Mechanical) program at North Eastern Regional Institute of Science and Technology focuses on advanced principles of thermodynamics, fluid mechanics, heat and mass transfer, and their applications in energy systems. The program emphasizes sustainable energy solutions, efficient thermal system design, and computational methods, aligning with India''''s growing demand for energy conservation and renewable technologies across various sectors. It aims to develop specialists for cutting-edge thermal engineering challenges.
Who Should Apply?
This program is ideal for Mechanical Engineering graduates with a strong aptitude for thermal sciences, seeking to specialize in energy conversion, propulsion, and advanced fluid dynamics. It also caters to working professionals in power generation, HVAC, automotive, and manufacturing sectors who aim to upgrade their skills for R&D roles, energy auditing, or advanced design positions in Indian industries. A valid GATE score is a prerequisite, indicating a competitive and merit-based entry.
Why Choose This Course?
Graduates of this program can expect diverse and rewarding career paths in India, including roles in thermal power plants, renewable energy companies (solar, wind, biomass), HVAC design and consulting, automotive R&D, and government research organizations like DRDO or ISRO. Entry-level salaries typically range from INR 6-10 LPA, with experienced professionals earning significantly more in leadership or specialized technical roles. The program prepares students for leadership in energy management, system optimization, and sustainable technology development.
Student Success Practices
Foundation Stage
Build Strong Analytical & Computational Foundations- (Semester 1-2)
Focus on thoroughly understanding core subjects like Advanced Thermodynamics, Heat & Mass Transfer, and Fluid Mechanics. Simultaneously, develop proficiency in computational tools and software learned in ''''Computational Methods in Thermal Engineering'''' by practicing regularly. Form study groups to solve complex problems and discuss concepts for deeper understanding.
Tools & Resources
MATLAB, ANSYS (Fluent/CFX), OpenFOAM (for basic CFD), online courses on numerical methods, university library resources
Career Connection
A strong foundation in these areas is crucial for all thermal engineering roles, enabling effective design, analysis, and simulation, highly valued by R&D and design firms in India.
Engage Actively in Lab & Research Methodology- (Semester 1-2)
Maximize learning from ''''Advanced Thermal Engineering Lab-I & II'''' by meticulously performing experiments, analyzing data, and writing comprehensive reports. Attend the ''''Research Methodology'''' course with an eye towards identifying potential dissertation topics and understanding academic writing standards. Proactively discuss research interests and ideas with faculty members.
Tools & Resources
Lab equipment, data analysis software (Excel, MATLAB), research paper databases (Scopus, Web of Science), NERIST library portal
Career Connection
Hands-on lab experience develops practical skills, while research methodology knowledge is essential for dissertation work and future R&D careers in Indian research institutions and industries.
Explore Renewable Energy & Energy Management- (Semester 1-2)
Deep dive into ''''Renewable Energy Systems'''' and ''''Energy Conservation and Management'''' courses. Attend seminars, workshops, and webinars related to these fields to grasp current trends and challenges. Consider joining relevant student clubs or initiatives focused on sustainability to gain practical exposure and network with like-minded individuals and experts.
Tools & Resources
NPTEL courses on energy, IRENA reports, journals like ''''Renewable and Sustainable Energy Reviews'''', industry conferences
Career Connection
These skills are highly sought after in India''''s rapidly expanding renewable energy sector, energy consulting firms, and industries focusing on energy efficiency and sustainability initiatives.
Intermediate Stage
Strategic Elective Selection & Specialization- (Semester 3)
Carefully choose elective subjects (MTS-E1, MTS-E2, MTS-E3) in consultation with faculty and supervisor, aligning with your career aspirations or potential dissertation topic. Focus on gaining deep expertise in selected areas like CFD, turbomachinery, or advanced IC engines, rather than just passing the courses. Utilize online advanced learning platforms for supplementary knowledge.
Tools & Resources
MOOCs (Coursera, edX) for specialized topics, advanced textbooks, research papers in chosen elective areas, LinkedIn Learning
Career Connection
Specializing through electives makes you a niche expert, increasing employability in specific thermal engineering domains like aerospace, automotive, or power generation in India''''s competitive market.
Initiate Dissertation Research & Literature Review- (Semester 3)
For ''''Dissertation Part-I'''', identify a challenging and relevant research problem in consultation with your supervisor. Conduct a thorough literature review, define clear research objectives, and develop a robust methodology (experimental, numerical, or analytical). Actively participate in departmental research discussions and present your preliminary findings.
Tools & Resources
Research paper databases (Scopus, Web of Science, Google Scholar), academic writing tools (Mendeley, Zotero), NERIST research labs
Career Connection
A strong start to your dissertation demonstrates research aptitude, critical thinking, and structured problem-solving, which are key for R&D positions and future academic pursuits like Ph.D. in India.
Gain Early Industry Exposure through Training- (Semester 3)
Actively participate in the ''''Industrial Training'''' program. Seek out opportunities in relevant industries (e.g., thermal power plants, manufacturing units, energy consulting firms) to gain practical experience. Focus on understanding real-world thermal systems, operational challenges, and gaining practical skills that complement theoretical knowledge. Document learnings meticulously.
Tools & Resources
Industrial training reports, company visits, discussions with industry mentors, networking events
Career Connection
Early industry exposure enhances your resume value, provides practical insights, and can open doors for future internships or placements in leading Indian and global companies operating in India.
Advanced Stage
Execute & Conclude High-Impact Dissertation- (Semester 4)
For ''''Dissertation Part-II'''', rigorously execute the planned methodology, collect and analyze data, interpret results, and prepare a high-quality thesis. Seek regular feedback from your supervisor and peers. Aim to present your findings in departmental seminars and consider publishing in peer-reviewed conferences or journals for wider academic recognition.
Tools & Resources
Specialized simulation software (ANSYS, MATLAB, COMSOL), experimental setups, statistical analysis tools, thesis writing guidelines, academic publication portals
Career Connection
A well-executed dissertation is a strong portfolio piece, demonstrating advanced problem-solving, research capabilities, and technical expertise, crucial for R&D roles, academia, and high-level engineering positions in India.
Master Placement Readiness & Interview Skills- (Semester 4)
Actively participate in campus placement drives. Refine your resume and cover letter, focusing on your M.Tech specialization, dissertation work, and relevant projects. Practice technical interviews, particularly for core thermal engineering roles, and work on soft skills like communication, teamwork, and presentation. Network with alumni for insights and mentorship.
Tools & Resources
Career development cell workshops, mock interview sessions, online interview preparation platforms (e.g., Glassdoor, LinkedIn), alumni network
Career Connection
This stage is critical for securing a desired placement, enabling a smooth and successful transition from academics to a professional career in the thermal science domain within India''''s job market.
Continuous Learning & Professional Development- (Semester 4)
Beyond coursework, commit to continuous learning in emerging thermal technologies (e.g., AI in energy, advanced materials for heat transfer, sustainable cooling). Consider pursuing relevant professional certifications (e.g., Certified Energy Manager) if applicable to your career path. Stay updated with industry trends through technical journals, webinars, and professional bodies like ISHRAE or ASME.
Tools & Resources
Professional societies (ASME, ISHRAE), industry whitepapers, advanced certifications, specialized webinars
Career Connection
Lifelong learning ensures career growth, adaptability to new technologies, and a sustained competitive advantage in the dynamic thermal engineering sector, allowing you to contribute meaningfully to India''''s energy landscape.
Program Structure and Curriculum
Eligibility:
- Bachelor''''s Degree in Mechanical Engineering / Mechanical & Automation Engineering / Production Engineering / Marine Engineering / Aerospace Engineering or equivalent from a recognized University / Institute with at least 6.5 CGPA on a 10-point scale or 60% aggregate marks, and valid GATE score. For NERIST regular employees, 55% marks are acceptable.
Duration: 4 semesters / 2 years
Credits: 68 Credits
Assessment: Assessment pattern not specified
Semester-wise Curriculum Table
Semester 1
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| MTS-101 | Advanced Thermodynamics | Core | 4 | Review of Laws of Thermodynamics, Availability and Irreversibility Analysis, Thermodynamic Relations for Real Gases, Chemical Equilibrium and Phase Transitions, Advanced Power and Refrigeration Cycles |
| MTS-102 | Advanced Heat and Mass Transfer | Core | 4 | Conduction Heat Transfer in Complex Geometries, Convection (Forced and Natural) Analysis, Thermal Radiation and Radiative Properties, Phase Change Heat Transfer (Boiling, Condensation), Heat Exchanger Design and Performance, Principles of Mass Transfer |
| MTS-103 | Advanced Fluid Mechanics | Core | 4 | Review of Fluid Properties and Governing Equations, Incompressible Viscous Flows, Boundary Layer Theory, Turbulent Flow Fundamentals, Compressible Flow and Gas Dynamics, Potential Flow Theory |
| MTS-104 | Computational Methods in Thermal Engineering | Core | 4 | Numerical Solutions of Differential Equations, Finite Difference Method, Finite Volume Method, Introduction to CFD and Grid Generation, Solution Algorithms for Fluid Flow and Heat Transfer, Error Analysis and Stability |
| MTS-105 | Advanced Thermal Engineering Lab-I | Lab | 2 | IC Engine Performance and Emission Analysis, Refrigeration and Air Conditioning System Tests, Heat Exchanger Performance Evaluation, Fluid Flow Measurement Techniques, Combustion and Flue Gas Analysis |
| MTS-106 | Research Methodology | Core | 2 | Problem Formulation and Literature Review, Research Design and Data Collection Methods, Sampling Techniques and Statistical Analysis, Hypothesis Testing and Regression Analysis, Technical Report Writing and Referencing, Research Ethics and Plagiarism |
Semester 2
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| MTS-201 | Renewable Energy Systems | Core | 4 | Solar Thermal and Photovoltaic Systems, Wind Energy Conversion Systems, Biomass and Biofuel Technologies, Geothermal and Ocean Thermal Energy, Hybrid Renewable Energy Systems, Energy Storage Technologies |
| MTS-202 | Energy Conservation and Management | Core | 4 | Energy Audit Methodology and Instruments, Energy Conservation in Thermal Systems, Waste Heat Recovery Technologies, Demand Side Management and Load Analysis, Energy Efficiency in Buildings and Utilities, Energy Economics and Policy |
| MTS-E1 | Elective-I | Elective | 4 | Selected from a list of specialized thermal engineering subjects based on student interest and supervisor consultation. Examples include Heat Exchanger Design, CFD, Advanced IC Engines, etc. |
| MTS-E2 | Elective-II | Elective | 4 | Selected from a list of specialized thermal engineering subjects based on student interest and supervisor consultation. Examples include Heat Exchanger Design, CFD, Advanced IC Engines, etc. |
| MTS-203 | Advanced Thermal Engineering Lab-II | Lab | 2 | Experiments on Solar Energy Systems, Wind Tunnel Testing and Aerodynamics, Advanced Combustion Analysis, Heat Pipe Performance Studies, Thermal Comfort and HVAC Systems |
| MTS-204 | Seminar | Project/Seminar | 2 | Technical Topic Selection and Literature Review, Preparation of Presentation Slides, Effective Oral Presentation Techniques, Question and Answer Session Management, Seminar Report Writing |
Semester 3
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| MTS-E3 | Elective-III | Elective | 4 | Selected from a list of specialized thermal engineering subjects based on student interest and supervisor consultation. Examples include Heat Exchanger Design, CFD, Advanced IC Engines, etc. |
| MTS-301 | Dissertation Part-I | Project | 10 | Problem Identification and Scope Definition, Extensive Literature Survey, Formulation of Research Objectives, Development of Methodology (Experimental/Numerical), Preliminary Data Collection/Simulation Setup, Interim Report and Presentation |
| MTS-302 | Industrial Training | Project/Internship | 2 | Understanding Industrial Processes and Operations, Application of Thermal Engineering Principles in Industry, Exposure to Real-world Equipment and Challenges, Observation of Safety and Quality Standards, Industrial Training Report Preparation |
Semester 4
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| MTS-401 | Dissertation Part-II | Project | 12 | Experimental/Numerical Work Execution, Data Analysis and Interpretation, Discussion of Results and Findings, Conclusion and Future Scope, Thesis Writing and Formatting, Viva-Voce Examination |
Semester subjects
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| MTS-E (General) | Heat Exchanger Design | Elective | 4 | Types and Classification of Heat Exchangers, LMTD and NTU Methods for Design, Compact Heat Exchanger Technology, Fouling and Performance Degradation, Thermal-Hydraulic Design Considerations, Advanced Heat Exchanger Materials |
| MTS-E (General) | Fluidized Bed Combustion | Elective | 4 | Fluidization Regimes and Characteristics, Fluidized Bed Reactor Design, Heat Transfer in Fluidized Beds, Combustion Principles in FBC, Emission Control in FBC Systems, Applications of FBC Technology |
| MTS-E (General) | Cryogenic Engineering | Elective | 4 | Principles of Low Temperature Production, Cryocoolers and Liquefiers, Cryogenic Insulation and Storage Systems, Cryogenic Fluid Properties, Applications of Cryogenics (Space, Medical, Energy), Safety in Cryogenic Systems |
| MTS-E (General) | Computational Fluid Dynamics (CFD) | Elective | 4 | Governing Equations of Fluid Flow and Heat Transfer, Discretization Techniques (FDM, FVM), Grid Generation and Meshing Strategies, Turbulence Modeling (RANS, LES, DNS), Post-processing and Visualization, CFD Software Applications |
| MTS-E (General) | Advanced Internal Combustion Engines | Elective | 4 | Thermodynamics of Engine Cycles, Combustion Phenomena and Kinetics, Pollutant Formation and Control, Alternative Fuels and Engine Technologies, Engine Performance and Emission Characteristics, Hybrid and Electric Vehicle Powertrains |
| MTS-E (General) | Refrigeration and Air Conditioning Systems | Elective | 4 | Vapor Compression and Absorption Refrigeration Cycles, Refrigerants and Environmental Impact, Psychrometry and Air Conditioning Processes, HVAC System Design and Components, Thermal Comfort and Indoor Air Quality, Energy Efficiency in RAC Systems |
| MTS-E (General) | Energy Management in Buildings | Elective | 4 | Building Energy Audit and Simulation, Passive and Active Building Design Strategies, HVAC System Optimization for Buildings, Lighting and Appliance Efficiency, Building Energy Codes and Standards, Smart Buildings and Automation |
| MTS-E (General) | Fuels and Combustion | Elective | 4 | Properties of Solid, Liquid, and Gaseous Fuels, Combustion Thermodynamics and Kinetics, Flame Propagation and Stability, Combustion in IC Engines and Furnaces, Pollutant Formation and Control Technologies, Advanced Combustion Concepts |
| MTS-E (General) | Gas Dynamics | Elective | 4 | Isentropic Flow Through Nozzles and Diffusers, Normal and Oblique Shocks, Prandtl-Meyer Expansion Waves, Fanno and Rayleigh Flow, Flow with Friction and Heat Transfer, Applications in Jet Propulsion and Turbomachinery |
| MTS-E (General) | Turbomachinery | Elective | 4 | Principle of Turbomachines and Classification, Impulse and Reaction Turbines (Steam, Gas), Centrifugal and Axial Compressors, Pumps and Fans, Performance Characteristics and Similarity Laws, Design and Analysis of Blades |
| MTS-E (General) | Non-Conventional Energy Sources | Elective | 4 | Solar Photovoltaic and Thermal Systems, Wind Power Generation and Technologies, Biomass Gasification and Combustion, Geothermal Energy Principles, Ocean Thermal Energy Conversion (OTEC), Fuel Cells and Hydrogen Energy |
| MTS-E (General) | Thermal Power Plant Engineering | Elective | 4 | Coal-Fired Power Plant Cycles, Boilers and Steam Generators, Turbines, Condensers, and Cooling Towers, Combined Cycle Power Plants, Nuclear Power Plant Fundamentals, Environmental Impact and Control Technologies |
| MTS-E (General) | Modelling & Simulation of Thermal Systems | Elective | 4 | Mathematical Modelling of Thermal Processes, Numerical Methods for System Simulation, Dynamic Modelling of Thermal Systems, Parameter Estimation and Optimization, Software Tools for Thermal System Simulation, Case Studies in Energy Systems |
| MTS-E (General) | Waste to Energy | Elective | 4 | Sources and Types of Waste, Thermal Conversion Technologies (Incineration, Pyrolysis), Biochemical Conversion Technologies (Anaerobic Digestion), Waste to Energy Plant Design, Environmental Impact and Regulations, Energy Recovery from Industrial and Municipal Waste |
| MTS-E (General) | Micro/Nano-scale Heat Transfer | Elective | 4 | Fundamentals of Microscale Heat Transfer, Heat Conduction in Thin Films, Microchannel Heat Sinks, Nano-fluid Heat Transfer, Thermal Management in Micro/Nano Devices, Experimental Techniques for Microscale Heat Transfer |
