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B-TECH in Chemical Engineering at Indian Institute of Technology Tirupati
Tirupati, Andhra Pradesh
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About the Specialization
What is Chemical Engineering at Indian Institute of Technology Tirupati Tirupati?
This Chemical Engineering program at Indian Institute of Technology Tirupati focuses on fundamental principles of process design, development, and optimization crucial for transforming raw materials into valuable products. The curriculum emphasizes core chemical engineering disciplines like thermodynamics, transport phenomena, and reaction engineering, preparing students for diverse roles in India''''s rapidly growing chemical, petrochemical, and allied industries. The program also integrates modern aspects such as sustainability, process simulation, and data analytics.
Who Should Apply?
This program is ideal for aspiring engineers and science graduates who possess strong analytical skills and a keen interest in applied chemistry, physics, and mathematics. it caters to fresh 10+2 graduates seeking entry into the core manufacturing and process sectors, as well as those aiming for research and development roles. individuals passionate about developing sustainable industrial solutions and optimizing complex chemical processes will find this specialization particularly rewarding.
Why Choose This Course?
Graduates of this program can expect diverse career paths in India across sectors like petroleum, pharmaceuticals, food processing, materials, and environmental management. Entry-level salaries typically range from INR 6-12 lakhs per annum, with significant growth potential to INR 20+ lakhs for experienced professionals. The curriculum prepares students for roles such as Process Engineer, R&D Scientist, Design Engineer, and Consultant, aligning with professional certifications and industry-specific skill demands.
Student Success Practices
Foundation Stage
Master Core Engineering Fundamentals- (Semester 1-2)
Focus diligently on Mathematics, Physics, Chemistry, and basic programming. Utilize online platforms like NPTEL for deeper understanding and practice problems regularly to build a strong analytical foundation essential for advanced chemical engineering concepts.
Tools & Resources
NPTEL, MIT OpenCourseware, Khan Academy
Career Connection
A strong foundation in core sciences is crucial for understanding complex chemical processes and forms the bedrock for all future engineering applications, improving analytical skills required by employers.
Develop Strong Problem-Solving Habits- (Semester 1-2)
Actively participate in tutorials and laboratory sessions, emphasizing a systematic approach to problem-solving. Engage in peer learning groups and utilize resources like GeeksforGeeks for programming challenges, improving logical reasoning and computational thinking vital for chemical process analysis.
Tools & Resources
GeeksforGeeks, HackerRank, Peer study groups
Career Connection
Enhanced problem-solving abilities are highly valued in R&D, process optimization, and design roles, leading to better internship and placement opportunities.
Explore Interdisciplinary Applications- (Semester 1-2)
Attend departmental seminars and industry talks to understand the broad applications of chemical engineering. Look for opportunities to engage with faculty on small projects or reading groups that connect foundational sciences to real-world engineering problems, fostering early career interest and clarity.
Tools & Resources
Departmental seminars, Industry webinars, Faculty mentorship
Career Connection
Early exposure to diverse applications helps in identifying niche interests and opens doors to interdisciplinary roles in industries like biotech, materials, or energy.
Intermediate Stage
Gain Practical Industry Exposure- (Semester 3-5)
Actively seek and complete summer internships in chemical, petrochemical, or pharmaceutical companies. This hands-on experience bridges theoretical knowledge with industrial practices, providing valuable insights into process operations, safety protocols, and equipment design.
Tools & Resources
Institute placement cell, LinkedIn, Company career pages
Career Connection
Internships are critical for practical skill development, networking, and often lead to pre-placement offers or preferential hiring in relevant industries.
Specialize through Electives and Projects- (Semester 3-5)
Carefully choose professional electives based on career interests, whether in biochemical engineering, materials science, or process control. Engage in departmental projects or research under faculty guidance to develop specialized skills and a deeper understanding of specific chemical engineering domains.
Tools & Resources
Faculty advisors, Course catalogs, Research papers
Career Connection
Specialized knowledge enhances competitiveness for targeted roles and advanced studies, making candidates more attractive to employers seeking specific expertise.
Network and Participate in Competitions- (Semester 3-5)
Join student chapters of professional bodies like the Indian Institute of Chemical Engineers (IIChE) and attend workshops and conferences. Participate in technical competitions, hackathons, or design challenges to apply learned skills, gain recognition, and build a professional network.
Tools & Resources
IIChE student chapter, Technical fests, Industry conferences
Career Connection
Networking opens doors to mentorship and job opportunities, while competition success demonstrates practical skills and problem-solving prowess to potential employers.
Advanced Stage
Focus on Industrial Readiness and Design- (Semester 6-8)
Engage thoroughly in Process Plant Design and Computer-Aided Process Engineering courses, utilizing simulation software like Aspen HYSYS or MATLAB/Simulink for real-world design challenges. Prepare a portfolio of design projects that showcase problem-solving and technical capabilities.
Tools & Resources
Aspen HYSYS, MATLAB/Simulink, CAD software
Career Connection
Proficiency in industry-standard simulation and design tools is a key requirement for roles in process design, engineering consultancy, and R&D, significantly boosting employability.
Intensify Placement Preparation- (Semester 6-8)
Dedicate time to developing a strong resume, practicing interview skills, and understanding common aptitude tests. Leverage the institute''''s career development cell for mock interviews, group discussions, and guidance on target companies, focusing on core chemical engineering roles.
Tools & Resources
Career Development Cell, Mock interviews, Aptitude test platforms
Career Connection
Effective placement preparation ensures graduates are well-equipped to secure desirable job offers from top-tier companies in the chemical and process industries.
Pursue Advanced Research or Entrepreneurship- (Semester 6-8)
For students interested in higher studies, focus on your final year project for a strong research output, potentially leading to publications. For entrepreneurial aspirants, explore incubators, develop a business plan, and connect with mentors in the chemical startup ecosystem in India to translate innovative ideas into ventures.
Tools & Resources
Research labs, Incubation centers, Startup mentorship programs
Career Connection
High-quality research can lead to M.Tech/Ph.D. admissions or R&D positions, while entrepreneurial skills can lead to founding impactful ventures in emerging chemical technology sectors.
Program Structure and Curriculum
Eligibility:
- Successful completion of 10+2 with Physics, Chemistry, and Mathematics, and qualification in JEE Advanced with rank within cut-offs specified by JoSAA/IIT Tirupati. Minimum 75% aggregate marks (65% for SC/ST/PwD) in 10+2 board examination.
Duration: 8 semesters / 4 years
Credits: 191 Credits
Assessment: Internal: 40%, External: 60%
Semester-wise Curriculum Table
Semester 1
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| MA101 | Mathematics-I | Core | 4 | Differential Calculus, Integral Calculus, Multivariable Calculus, Vector Calculus, Infinite Series |
| PH101 | Physics | Core | 4 | Classical Mechanics, Special Relativity, Oscillations and Waves, Optics, Quantum Mechanics |
| CH101 | Chemistry | Core | 3 | Quantum Chemistry, Spectroscopy, Chemical Bonding, Organic Reaction Mechanisms, Solid State Chemistry |
| CH103 | Engineering Chemistry Lab | Lab | 1.5 | Volumetric Analysis, Instrumental Methods, Synthesis Experiments, Physical Chemistry Experiments, Characterization Techniques |
| CS101 | Introduction to Programming | Core | 3 | Programming Fundamentals, Data Types and Variables, Control Structures, Functions and Modules, Basic Algorithms |
| CS103 | Introduction to Programming Lab | Lab | 1.5 | Problem Solving with C, Data Structures Implementation, Debugging Techniques, Algorithm Design, Practical Programming Exercises |
| EE101 | Basic Electrical Engineering | Core | 3 | DC Circuits, AC Circuits, Transformers, Electrical Machines, Power Systems Introduction |
| EE103 | Basic Electrical Engineering Lab | Lab | 1.5 | DC and AC Circuit Experiments, Transformer Testing, Motor Characteristics, Power Measurement, Basic Electronics |
| ME101 | Engineering Graphics | Core | 2.5 | Orthographic Projections, Isometric Projections, Sections of Solids, Development of Surfaces, CAD Software Introduction |
| CE101 | Environmental Studies | Core | 2 | Natural Resources, Ecosystems, Biodiversity, Environmental Pollution, Social Issues and Environment |
| HS101 | English for Communication | Core | 2 | Grammar and Usage, Reading Comprehension, Public Speaking, Report Writing, Presentation Skills |
| HS103 | English for Communication Lab | Lab | 1 | Phonetics and Pronunciation, Group Discussions, Debates, Interview Skills, Listening Comprehension |
Semester 2
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| MA102 | Mathematics-II | Core | 4 | Ordinary Differential Equations, Laplace Transforms, Fourier Series, Partial Differential Equations, Complex Analysis |
| PH102 | Waves and Optics | Core | 4 | Wave Motion, Superposition of Waves, Interference, Diffraction, Polarization, Lasers |
| PH104 | Physics Lab | Lab | 1.5 | Mechanics Experiments, Optics Experiments, Thermal Physics Experiments, Electricity and Magnetism, Semiconductor Devices |
| ME102 | Engineering Mechanics | Core | 4 | Statics of Particles and Rigid Bodies, Equilibrium, Friction, Dynamics of Particles, Kinematics and Kinetics |
| ME104 | Engineering Workshop | Lab | 1.5 | Carpentry, Fitting, Welding, Machining, Sheet Metal Work, Foundry Practices |
| CE102 | Basic Civil Engineering | Core | 3 | Building Materials, Surveying, Structural Engineering Principles, Transportation Engineering, Water Resources Engineering |
| CE104 | Basic Civil Engineering Lab | Lab | 1.5 | Material Testing (Concrete, Steel), Surveying Practicals, Soil Mechanics Tests, Fluid Mechanics Experiments |
| BT101 | Introduction to Biology | Core | 2 | Cell Biology, Genetics, Molecular Biology, Microbiology, Human Physiology |
| CH102 | Chemical Process Calculations | Core | 4 | Units and Dimensions, Material Balances, Energy Balances, Thermodynamic Properties of Fluids, Vapour-Liquid Equilibria, Recycle and Purge Operations |
| CH104 | Fluid Mechanics Lab | Lab | 1.5 | Fluid Flow Measurement, Pipe Friction, Pump Performance, Flow through Orifices and Venturis, Packed and Fluidized Beds |
| HS102 | Professional Ethics & Human Values | Core | 2 | Ethical Theories, Engineering Ethics, Human Values, Corporate Social Responsibility, Environmental Ethics |
Semester 3
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| MA201 | Mathematics-III | Core | 4 | Linear Algebra, Probability and Statistics, Sampling Distributions, Hypothesis Testing, Regression Analysis |
| CH201 | Fluid Mechanics | Core | 4 | Fluid Statics, Bernoulli''''s Equation, Laminar and Turbulent Flow, Flow Measurement, Pumps and Compressors |
| CH203 | Thermodynamics for Chemical Engineering | Core | 4 | First and Second Laws of Thermodynamics, PVT Behavior, Phase Equilibria, Chemical Reaction Equilibria, Refrigeration Cycles |
| CH205 | Chemical Technology | Core | 3 | Inorganic Chemical Industries, Organic Chemical Industries, Petrochemicals, Polymers, Fermentation Technology |
| CH207 | Solid Mechanics for Chemical Engineering | Core | 3 | Stress and Strain, Elasticity, Bending and Shear, Torsion, Pressure Vessels |
| CH209 | Heat Transfer | Core | 4 | Conduction, Convection, Radiation, Heat Exchangers, Evaporators |
| CH211 | Chemical Engineering Thermodynamics Lab | Lab | 1.5 | Calorimetry Experiments, Phase Equilibria, Refrigeration Cycle Performance, Heat of Mixing, Vapour Pressure Measurement |
| CH213 | Heat Transfer Lab | Lab | 1.5 | Conduction Heat Transfer, Convection Heat Transfer, Radiation Heat Transfer, Heat Exchanger Performance, Extended Surfaces |
Semester 4
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| CH202 | Mass Transfer-I | Core | 4 | Molecular Diffusion, Convective Mass Transfer, Interphase Mass Transfer, Distillation Principles, Absorption and Stripping |
| CH204 | Chemical Reaction Engineering-I | Core | 4 | Reaction Kinetics, Batch Reactors, Continuous Stirred Tank Reactors, Plug Flow Reactors, Multiple Reactions and Selectivity |
| CH206 | Chemical Engineering Drawing & Graphics | Core | 2.5 | Process Flow Diagrams (PFD), Piping & Instrumentation Diagrams (P&ID), Equipment Layout, Orthographic Projections, CAD Applications |
| CH208 | Mechanical Operations | Core | 4 | Particle Characterization, Fluidization, Sedimentation, Filtration, Crushing and Grinding |
| CH210 | Process Instrumentation & Control | Core | 4 | Measurement of Process Variables, Transducers and Sensors, Control System Components, PID Controllers, Stability Analysis of Control Systems |
| CH212 | Mass Transfer Lab | Lab | 1.5 | Diffusion Coefficient Measurement, Gas Absorption, Liquid-Liquid Extraction, Distillation, Drying |
| CH214 | Mechanical Operations Lab | Lab | 1.5 | Particle Size Analysis, Filtration Studies, Crushing and Grinding, Fluidized Bed Studies, Cyclone Separator |
| HSXXX | Humanities Elective | Elective | 2 | Student chooses from a list of Humanities and Social Sciences Electives |
Semester 5
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| CH301 | Mass Transfer-II | Core | 4 | Liquid-Liquid Extraction, Adsorption, Ion Exchange, Crystallization, Membrane Separations |
| CH303 | Chemical Reaction Engineering-II | Core | 4 | Heterogeneous Catalysis, Non-Ideal Flow, Multiphase Reactors, Fixed and Fluidized Bed Reactors, Bioreactors |
| CH305 | Process Dynamics & Control Lab | Lab | 1.5 | PID Controller Tuning, Process Response Characteristics, Level Control Systems, Temperature Control Systems, Flow Control Systems |
| CH307 | Chemical Engineering Design | Core | 4 | Process Synthesis, Equipment Design Principles, Cost Estimation and Economic Evaluation, Safety Analysis and HAZOP, Project Design and Management |
| CH309 | Industrial Pollution Control | Core | 3 | Air Pollution Control Technologies, Water Pollution Treatment, Solid Waste Management, Hazardous Waste Management, Environmental Impact Assessment |
| CH311 | Mass Transfer & CRE Lab | Lab | 1.5 | Adsorption Isotherms, Ion Exchange Operations, Batch Reactor Studies, Continuous Reactor Studies, Packed Bed Reactor Performance |
| PEC-I | Professional Elective-I | Elective | 3 | Student chooses one from: Polymer Science and Engineering, Biochemical Engineering, Computational Fluid Dynamics (CFD), Petroleum Refining Engineering |
| CH313 | Polymer Science and Engineering | Elective (PEC-I option) | 3 | Polymerization Mechanisms, Polymer Characterization, Rheology of Polymers, Polymer Processing, Applications of Polymers |
| CH315 | Biochemical Engineering | Elective (PEC-I option) | 3 | Bioreactor Design, Enzyme Kinetics, Microbial Fermentations, Downstream Processing, Bioseparations |
| CH317 | Computational Fluid Dynamics (CFD) | Elective (PEC-I option) | 3 | Governing Equations of Fluid Flow, Numerical Methods in CFD, Discretization Techniques, Turbulence Modeling, CFD Software Applications |
| CH319 | Petroleum Refining Engineering | Elective (PEC-I option) | 3 | Crude Oil Properties, Atmospheric and Vacuum Distillation, Cracking and Reforming, Product Treatment, Refinery Operations |
| PEC-II | Professional Elective-II | Elective | 3 | Student chooses one from: Advanced Separation Processes, Energy Engineering, Materials Science and Engineering, Optimization Techniques in Chemical Engineering |
| CH321 | Advanced Separation Processes | Elective (PEC-II option) | 3 | Supercritical Fluid Extraction, Reactive Distillation, Adsorptive Separations, Chromatographic Separations, Membrane Contactors |
| CH323 | Energy Engineering | Elective (PEC-II option) | 3 | Conventional Energy Sources, Renewable Energy Technologies, Energy Conservation and Audit, Fuel Cells, Biofuels Production |
| CH325 | Materials Science and Engineering | Elective (PEC-II option) | 3 | Structure-Property Relationship, Metals and Alloys, Ceramics and Glasses, Polymers and Composites, Material Characterization |
| CH327 | Optimization Techniques in Chemical Engineering | Elective (PEC-II option) | 3 | Linear Programming, Non-Linear Programming, Integer Programming, Dynamic Programming, Process Optimization Strategies |
Semester 6
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| CH302 | Transport Phenomena | Core | 4 | Momentum Transport, Energy Transport, Mass Transport, Analogies in Transport, Turbulent Transport Phenomena |
| CH304 | Process Engineering Economics | Core | 3 | Time Value of Money, Cash Flow Analysis, Project Evaluation Techniques, Cost Estimation Methods, Depreciation and Taxation |
| CH306 | Process Simulation & Modelling Lab | Lab | 1.5 | Process Flowsheet Simulation (e.g., Aspen Plus), Mathematical Modelling of Processes, Parameter Estimation, Dynamic Simulation, Optimization using Software |
| CH308 | Fluid and Particulate Systems Lab | Lab | 1.5 | Non-Newtonian Fluid Flow, Slurry Transport, Filtration Operations, Sedimentation, Drying Experiments |
| CH399 | Summer Internship | Project | 3 | Industrial Exposure, Application of Engineering Principles, Problem Solving in Industry, Technical Report Writing, Professional Development |
| PEC-III | Professional Elective-III | Elective | 3 | Student chooses one from: Process Intensification, Catalysis and Catalytic Reactors, Safety in Chemical Industry, Surface Science and Catalysis |
| CH314 | Process Intensification | Elective (PEC-III option) | 3 | Microreactors, Reactive Separations, High-Gravity Separations, Novel Reactor Designs, Energy Efficiency in Processes |
| CH316 | Catalysis and Catalytic Reactors | Elective (PEC-III option) | 3 | Homogeneous and Heterogeneous Catalysis, Catalyst Characterization, Reactor Types for Catalytic Reactions, Catalyst Deactivation, Industrial Catalytic Processes |
| CH318 | Safety in Chemical Industry | Elective (PEC-III option) | 3 | Hazard Identification and Analysis, Risk Assessment and Management, Accident Investigation, Process Safety Management, Emergency Planning and Response |
| CH320 | Surface Science and Catalysis | Elective (PEC-III option) | 3 | Surface Characterization Techniques, Adsorption Phenomena, Surface Reactions and Kinetics, Heterogeneous Catalysis Principles, Catalyst Preparation Methods |
| PEC-IV | Professional Elective-IV | Elective | 3 | Student chooses one from: Advanced Transport Phenomena, Polymer Reaction Engineering, Biochemical Process Engineering, Electrochemical Engineering |
| CH322 | Advanced Transport Phenomena | Elective (PEC-IV option) | 3 | Boundary Layer Theory, Turbulent Transport Models, Multicomponent Diffusion, Interfacial Phenomena, Non-Newtonian Fluid Flow |
| CH324 | Polymer Reaction Engineering | Elective (PEC-IV option) | 3 | Polymerization Kinetics, Reactor Design for Polymers, Polymer Rheology, Polymer Processing, Polymer Synthesis Methods |
| CH326 | Biochemical Process Engineering | Elective (PEC-IV option) | 3 | Sterilization Techniques, Fermentation Systems Design, Downstream Processing, Enzyme Technology, Biofuel Production Processes |
| CH328 | Electrochemical Engineering | Elective (PEC-IV option) | 3 | Electrochemistry Fundamentals, Electrolytic Cells, Batteries and Fuel Cells, Corrosion Engineering, Electrodialysis |
Semester 7
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| CH401 | Process Plant Design | Core | 3 | Plant Layout and Location, Piping Design Principles, Equipment Sizing and Specification, Utilities and Instrumentation Design, Material of Construction Selection |
| CH403 | Computer Aided Process Engineering | Core | 3.5 | Process Simulation Software (e.g., Aspen HYSYS), Optimization Tools in Process Design, Data Reconciliation, Steady State and Dynamic Simulation, Process Integration and Pinch Analysis |
| CH491 | Project Part-I | Project | 3 | Literature Review, Problem Definition and Scope, Methodology Development, Experimental Design or Simulation Plan, Preliminary Results and Analysis |
| OEC-I | Open Elective-I | Elective | 3 | Student chooses from institute-wide open electives offered by other departments |
| PEC-V | Professional Elective-V | Elective | 3 | Student chooses one from: Renewable Energy Systems, Nanomaterials and Applications, Process Modeling and Simulation, Process Data Analytics |
| CH411 | Renewable Energy Systems | Elective (PEC-V option) | 3 | Solar Energy Technologies, Wind Energy Conversion, Geothermal Energy, Biomass Energy Conversion, Hybrid Energy Systems |
| CH413 | Nanomaterials and Applications | Elective (PEC-V option) | 3 | Synthesis of Nanomaterials, Characterization Techniques for Nanomaterials, Nanocatalysis, Nanomembranes, Nanotechnology in Energy and Environment |
| CH415 | Process Modeling and Simulation | Elective (PEC-V option) | 3 | Mathematical Models for Chemical Processes, Numerical Methods for Solving ODEs/PDEs, Dynamic Simulation of Processes, Parameter Estimation and Model Validation, Advanced Control Strategies |
| CH417 | Process Data Analytics | Elective (PEC-V option) | 3 | Data Acquisition and Pre-processing, Statistical Process Monitoring, Machine Learning for Process Operations, Predictive Maintenance, Process Optimization using Data |
| PEC-VI | Professional Elective-VI | Elective | 3 | Student chooses one from: Carbon Capture and Utilization, Heterogeneous Catalysis and Reactor Design, Advanced Chemical Thermodynamics, Sustainable Chemical Processes |
| CH412 | Carbon Capture and Utilization | Elective (PEC-VI option) | 3 | Carbon Cycle and Climate Change, Carbon Capture Technologies (Post/Pre-Combustion), CO2 Conversion and Utilization, Carbon Sequestration, Policy and Economics of CCU |
| CH414 | Heterogeneous Catalysis and Reactor Design | Elective (PEC-VI option) | 3 | Catalyst Preparation and Characterization, Reaction Mechanisms on Surfaces, Fixed Bed Reactor Design, Fluidized Bed Reactor Design, Catalyst Deactivation and Regeneration |
| CH416 | Advanced Chemical Thermodynamics | Elective (PEC-VI option) | 3 | Statistical Thermodynamics, Molecular Simulation in Thermodynamics, Irreversible Thermodynamics, Phase Stability and Critical Phenomena, Theories of Mixtures |
| CH418 | Sustainable Chemical Processes | Elective (PEC-VI option) | 3 | Green Chemistry Principles, Life Cycle Assessment (LCA), Sustainable Process Design, Resource Efficiency and Circular Economy, Industrial Ecology |
Semester 8
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| CH492 | Project Part-II | Project | 6 | Experimental Execution and Data Collection, Advanced Data Analysis and Interpretation, Formulation of Conclusions and Recommendations, Technical Thesis Writing, Oral Presentation and Defense |
| OEC-II | Open Elective-II | Elective | 3 | Student chooses from institute-wide open electives offered by other departments |
