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B-TECH in Physics And Nano Technology at SRM Institute of Science and Technology (Deemed to be University)
Chengalpattu, Tamil Nadu
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About the Specialization
What is Physics and Nano Technology at SRM Institute of Science and Technology (Deemed to be University) Chengalpattu?
This B.Tech Physics and Nanotechnology program at SRM Institute of Science and Technology focuses on fundamental physics principles and their application in the burgeoning field of nanotechnology. It equips students with knowledge of quantum mechanics, material science, and nano-fabrication techniques, crucial for driving innovation in India''''s advanced manufacturing and high-tech sectors. The program emphasizes both theoretical understanding and practical skills, preparing graduates for cutting-edge research and industrial roles.
Who Should Apply?
This program is ideal for scientifically inclined fresh graduates who have a strong foundation in physics and mathematics, seeking entry into research and development in materials science, quantum computing, or biotechnology. It also suits individuals passionate about developing next-generation technologies, from energy solutions to medical devices. Aspiring engineers and scientists looking to contribute to India''''s burgeoning scientific landscape will find this program deeply rewarding.
Why Choose This Course?
Graduates of this program can expect diverse career paths in India, including R&D scientist, materials engineer, process engineer, or research associate in various industries like electronics, aerospace, defence, and pharmaceuticals. Entry-level salaries typically range from INR 4-7 lakhs per annum, with experienced professionals earning significantly more. The strong foundation in physics and nanotechnology also prepares students for higher studies, including M.Tech and Ph.D. programs in India and abroad.
Student Success Practices
Foundation Stage
Build Strong Mathematical and Physics Fundamentals- (Semester 1-2)
Focus intensely on core Engineering Mathematics and Physics concepts, which form the bedrock of nanotechnology. Regularly solve problems from textbooks and online platforms to solidify understanding, ensuring a robust conceptual foundation.
Tools & Resources
NPTEL courses for foundational subjects, Khan Academy, SRMIST academic support centers, Peer study groups
Career Connection
A robust understanding ensures success in advanced subjects and provides a strong base for analytical and research roles in physics and nanotechnology sectors.
Master Basic Programming and Data Structures- (Semester 1-2)
Develop proficiency in a programming language like C++ or Python and grasp fundamental data structures. Apply these skills actively in laboratory sessions and introductory project-based learning to build computational thinking.
Tools & Resources
HackerRank, CodeChef, GeeksforGeeks, Python/C++ documentation, SRMIST''''s computing labs
Career Connection
Essential for computational physics, data analysis in research, and developing simulations, opening doors to R&D and tech-driven roles in India.
Engage in Interdisciplinary Exploration- (Semester 1-2)
Actively participate in interdepartmental workshops, seminars, and clubs. Explore how physics principles integrate with other engineering disciplines like chemistry and electronics, fostering a broad technical perspective.
Tools & Resources
SRMIST''''s various student clubs, Departmental seminars, Guest lectures by industry experts
Career Connection
Fosters a broader perspective crucial for nanotechnology''''s interdisciplinary nature, leading to roles in diverse fields like bio-nanotech or advanced materials engineering.
Intermediate Stage
Dive Deep into Nanoscience Core Concepts- (Semester 3-5)
Focus on understanding quantum mechanics, material science, and the introduction to nanoscience and nanotechnology. Attend specialized workshops and seek out faculty mentors for research interests to gain specialized knowledge.
Tools & Resources
Specialized textbooks and research papers, Departmental research groups, NPTEL advanced courses in nanoscience
Career Connection
Builds the theoretical expertise required for advanced research positions, product development, and innovation in the nanotechnology sector.
Develop Hands-on Laboratory and Characterization Skills- (Semester 3-5)
Maximise learning from Solid State Physics, Material Characterization, and Nanomaterials Synthesis labs. Gain practical experience with instruments like XRD, SEM, and AFM, crucial for experimental research.
Tools & Resources
Lab manuals and online instrument tutorials, Departmental workshops on advanced characterization techniques, Mentorship from lab technicians
Career Connection
Essential for R&D roles in industry and academia, as practical skills in material synthesis and characterization are highly valued by Indian research labs and manufacturing firms.
Pursue Industry-Relevant Internships and Projects- (Semester 4-5)
Actively seek summer internships in research institutions or nanotechnology companies. Engage in Project Based Learning and mini-projects to apply theoretical knowledge to real-world problems and gain practical experience.
Tools & Resources
SRMIST''''s placement cell and career services, LinkedIn for industry contacts, Faculty project opportunities
Career Connection
Provides invaluable industry exposure, builds professional networks, and enhances employability for placements in India''''s growing advanced materials and electronics sectors.
Advanced Stage
Specialize and Conduct Independent Research- (Semester 6-8)
Choose electives aligned with specific interests (e.g., Nano-Biotechnology, Quantum Information Science) and dedicate significant effort to the year-long Project Work (Phase I & II). Aim for publications or patent submissions to showcase expertise.
Tools & Resources
Access to advanced labs and research databases (Scopus, Web of Science), Collaboration with faculty members on research, Opportunities for research grants
Career Connection
Positions graduates as experts in niche areas, making them highly desirable for research roles, M.Tech/Ph.D. admissions, and deep-tech startups in India.
Master Micro and Nano Fabrication Techniques- (Semester 6-7)
Gain expertise in advanced fabrication processes like lithography, thin-film deposition, and etching in specialized laboratories. Understand the full cycle of creating nanodevices from design to characterization.
Tools & Resources
Cleanroom access and specialized equipment training, Industry workshops on fabrication processes, Simulation software for device design
Career Connection
Directly prepares students for roles in semiconductor manufacturing, MEMS development, and advanced materials processing industries in India, which are rapidly expanding.
Prepare for Advanced Placements and Higher Education- (Semester 7-8)
Actively participate in campus placements, refine interview skills, and build a professional portfolio showcasing projects and research. Simultaneously prepare for competitive exams like GATE or GRE for higher studies and global opportunities.
Tools & Resources
SRMIST''''s career services and alumni network, Mock interviews and resume workshops, Online platforms for competitive exam preparation
Career Connection
Ensures successful transition into a professional career in leading Indian and international companies, or secures admission to top-tier academic programs for further specialization.
Program Structure and Curriculum
Eligibility:
- Minimum 50% aggregate in Physics, Chemistry, Mathematics / Biology / Biotechnology / Botany / Zoology in 12th Standard (or equivalent) AND a valid rank in SRMJEEE (UG) entrance examination.
Duration: 4 years / 8 semesters
Credits: 156 Credits
Assessment: Internal: 50% (Continuous Internal Assessment - CAT, Assignments, Quizzes), External: 50% (End Semester Examination)
Semester-wise Curriculum Table
Semester 1
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| 21BSH101J | Engineering Mathematics – I | Core | 4 | Matrices and System of Equations, Eigenvalues and Eigenvectors, Differential Calculus of Several Variables, Vector Calculus, Multiple Integrals |
| 21BSH102J | Engineering Physics | Core | 3 | Oscillations and Waves, Physical Optics, Quantum Physics, Laser Physics, Solid State Physics |
| 21BEE101J | Basic Electrical and Electronics Engineering | Core | 3 | DC and AC Circuits, Magnetic Circuits, Semiconductor Diodes, Transistors, Digital Logic Gates |
| 21BME101J | Engineering Graphics and Design | Core | 3 | Orthographic Projections, Sectional Views, Isometric Projections, Perspective Views, Computer Aided Drafting |
| 21BPD101J | Soft Skills | Core | 1 | Self-Introduction and Communication, Presentation Skills, Interpersonal Skills, Group Dynamics, Emotional Intelligence |
| 21BEX101J | Universal Human Values | Core | 2 | Understanding Harmony in Human Beings, Harmony in Family and Society, Harmony in Nature and Existence, Universal Human Order, Implications of Right Understanding |
| 21BSL102J | Physics Laboratory | Lab | 2 | Experiments on Optics, Interference and Diffraction, Measurements of Physical Constants, Semiconductor Device Characteristics, Material Properties |
| 21BEE102J | Basic Electrical and Electronics Engineering Laboratory | Lab | 2 | Verification of Circuit Laws, Characteristics of Diodes and Transistors, Logic Gate Operations, Transformer Experimentation, Motor Control |
| 21BME102J | Engineering Graphics and Design Laboratory | Lab | 2 | 2D Drafting using CAD Software, 3D Modeling and Assembly, Dimensioning and Tolerancing, Sectional and Auxiliary Views, Orthographic Projections |
Semester 2
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| 21BSH201J | Engineering Mathematics – II | Core | 4 | Ordinary Differential Equations, Laplace Transforms, Fourier Series, Complex Numbers and Functions, Analytic Functions |
| 21BSH203J | Engineering Chemistry | Core | 3 | Water Treatment, Electrochemistry and Corrosion, Fuels and Combustion, Polymers and Composites, Spectroscopic Techniques |
| 21BPH201J | Engineering Mechanics | Core | 3 | Statics of Particles and Rigid Bodies, Equilibrium and Friction, Centroid and Moment of Inertia, Kinematics of Particles, Work-Energy Principle |
| 21BPD201J | Professional Skills | Core | 1 | Verbal Ability, Quantitative Aptitude, Logical Reasoning, Problem Solving, Career Planning |
| 21BSL203J | Chemistry Laboratory | Lab | 2 | Volumetric Analysis, Water Quality Analysis, Corrosion Studies, Polymer Synthesis, Spectrophotometry |
| 21BCS201J | Programming and Data Structures | Core | 3 | C++ Programming Fundamentals, Arrays and Pointers, Functions and Classes, Linked Lists and Stacks, Queues and Trees |
| 21BCS202J | Programming and Data Structures Laboratory | Lab | 2 | C++ Program Development, Implementation of Data Structures, Sorting and Searching Algorithms, File Handling, Recursion |
| 21BPJ201J | Project Based Learning – I | Project | 1 | Problem Identification, Literature Survey, Basic Design Concepts, Prototyping Fundamentals, Technical Report Writing |
Semester 3
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| 21BSH301J | Probability and Statistical Methods | Core | 4 | Probability Theory, Random Variables and Distributions, Sampling Distributions, Hypothesis Testing, Regression and Correlation |
| 21BPH301J | Modern Physics | Core | 3 | Quantum Mechanics Introduction, Atomic Structure and Spectra, Nuclear Physics Fundamentals, Solid State Physics Basics, Lasers and Fiber Optics |
| 21BPH302J | Material Science | Core | 3 | Crystal Structures and Defects, Mechanical Properties of Materials, Phase Diagrams, Electrical Properties of Materials, Magnetic and Optical Properties |
| 21BPH303J | Thermodynamics and Statistical Mechanics | Core | 3 | Laws of Thermodynamics, Entropy and Free Energy, Kinetic Theory of Gases, Classical Statistics (Maxwell-Boltzmann), Quantum Statistics (Bose-Einstein, Fermi-Dirac) |
| 21BEN301J | Environmental Science and Sustainability | Core | 2 | Ecosystems and Biodiversity, Environmental Pollution, Renewable Energy Resources, Climate Change and Global Warming, Sustainable Development Goals |
| 21BPH304J | Solid State Physics Laboratory | Lab | 2 | X-ray Diffraction Studies, Hall Effect Measurements, Magnetic Susceptibility Determination, Dielectric Constant Measurement, Semiconductor Device Characterization |
| 21BPH305J | Material Characterization Laboratory | Lab | 2 | UV-Vis Spectroscopy, Fourier Transform Infrared (FTIR), Raman Spectroscopy, Scanning Electron Microscopy (SEM), Atomic Force Microscopy (AFM) |
| 21BPJ301J | Project Based Learning – II | Project | 1 | Advanced Problem Solving, Experimental Design and Execution, Data Analysis and Interpretation, Report Writing and Presentation, Team Collaboration |
Semester 4
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| 21BSH401J | Numerical Methods and Transform Techniques | Core | 4 | Solution of Algebraic Equations, Interpolation and Curve Fitting, Numerical Integration and Differentiation, Fourier Transforms, Z-Transforms |
| 21BPH401J | Quantum Mechanics | Core | 3 | Schrödinger Equation, Operators and Observables, Eigenvalues and Eigenfunctions, Approximation Methods, Scattering Theory |
| 21BPH402J | Electrodynamics | Core | 3 | Maxwell''''s Equations, Electromagnetic Wave Propagation, Poynting Vector and Energy Flow, Waveguides and Resonators, Radiation by Accelerated Charges |
| 21BPH403J | Introduction to Nanoscience and Nanotechnology | Core | 3 | Basics of Nanoscience, Quantum Effects at Nanoscale, Synthesis of Nanomaterials, Characterization Techniques, Applications of Nanomaterials |
| 21BPH404J | Condensed Matter Physics | Core | 3 | Crystal Lattices and Reciprocal Lattice, Band Theory of Solids, Superconductivity, Magnetism in Solids, Dielectric Properties of Materials |
| 21BPH405J | Nanomaterials Synthesis Laboratory | Lab | 2 | Chemical Vapor Deposition (CVD), Sol-Gel Synthesis, Hydrothermal Synthesis, Thin Film Deposition, Synthesis of Nanoparticles |
| 21BPH406J | Characterization of Nanomaterials Laboratory | Lab | 2 | Transmission Electron Microscopy (TEM), Scanning Tunneling Microscopy (STM), X-ray Diffraction (XRD), Dynamic Light Scattering (DLS), Zeta Potential Measurement |
| 21BPJ401J | Project Based Learning – III | Project | 1 | Research Methodology, Literature Review and Gap Analysis, Experimental Design and Analysis, Technical Presentation Skills, Report Preparation |
Semester 5
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| 21BPH501J | Optics and Lasers | Core | 3 | Wave Optics, Interference and Diffraction, Polarization, Laser Principles and Types, Applications of Lasers |
| 21BPH502J | Semiconductor Physics and Devices | Core | 3 | Semiconductor Fundamentals, PN Junction Diode, Bipolar Junction Transistors, Field-Effect Transistors, Optoelectronic Devices |
| 21BPH503J | Computational Physics | Core | 3 | Numerical Methods in Physics, Monte Carlo Simulation, Molecular Dynamics, Finite Element Method, Data Analysis and Visualization |
| 21BPH504J | Nanoelectronics | Core | 3 | Quantum Transport Phenomena, Single Electron Transistors, Spintronics, Molecular Electronics, Graphene and Carbon Nanotube Devices |
| 21BPH202E | Elective – I (e.g., Properties of Materials) | Elective | 3 | Mechanical Properties (Strength, Hardness), Thermal Properties (Conductivity, Expansion), Electrical Properties (Conductivity, Dielectric), Optical Properties (Absorption, Emission), Advanced Materials (Ceramics, Composites) |
| 21BPH505J | Advanced Physics Laboratory | Lab | 2 | Advanced Optical Experiments, Fiber Optic Communication, Laser Spectroscopy, Semiconductor Device Fabrication, Cryogenic Experiments |
| 21BPH506J | Nanoelectronics Laboratory | Lab | 2 | Nanodevice Simulation Software, Thin Film Characterization, Spintronics Experimentation, Quantum Dot Fabrication, Nanowire Device Measurement |
| 21BPH507J | Industrial Training / Internship (4 Weeks) | Project | 2 | Industry Exposure, Application of Theoretical Knowledge, Problem Solving in Industrial Setting, Technical Report Writing, Professional Networking |
Semester 6
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| 21BPH601J | Atomic and Molecular Physics | Core | 3 | Atomic Models and Spectra, Molecular Structure, Rotational Spectroscopy, Vibrational Spectroscopy, Raman Effect and Spectroscopy |
| 21BPH602J | Nano-Biotechnology | Core | 3 | Bio-Nanomaterials, Nanoparticles in Drug Delivery, Biosensors and Diagnostics, Nanomedicine, Bio-Imaging Techniques |
| 21BPH603J | Micro and Nano Fabrication | Core | 3 | Photolithography, Etching Techniques, Thin Film Deposition Methods, Doping Processes, Micro-Electro-Mechanical Systems (MEMS) |
| 21BPH407E | Elective – II (e.g., Nuclear and Particle Physics) | Elective | 3 | Nuclear Structure, Radioactivity and Decay, Nuclear Reactions, Elementary Particles, Standard Model |
| 21BPLXXXE | Open Elective – I | Elective | 3 | Topics vary based on chosen open elective from other departments, General courses from engineering, management, or humanities, Skill-based courses, Emerging technologies, Interdisciplinary applications |
| 21BPH604J | Micro and Nano Fabrication Laboratory | Lab | 2 | Photolithography Experimentation, Wet and Dry Etching, Thin Film Thickness Measurement, Device Patterning, Characterization of Fabricated Structures |
| 21BPH605J | Mini Project | Project | 2 | Project Planning and Management, Experimental Implementation, Data Collection and Analysis, Technical Report Writing, Project Presentation |
Semester 7
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| 21BPH701J | Quantum Information Science | Core | 3 | Quantum Computing Fundamentals, Qubits and Quantum Gates, Quantum Entanglement, Quantum Cryptography, Quantum Algorithms |
| 21BPH702J | Advanced Nanotechnology | Core | 3 | Carbon Nanostructures (Graphene, CNTs), Plasmonics, Self-Assembly in Nanotechnology, Nanophotonics, Advanced Nanocomposites |
| 21BPH508E | Elective – III (e.g., Physics of Thin Films) | Elective | 3 | Thin Film Deposition Techniques, Growth Mechanisms of Thin Films, Characterization of Thin Films, Electrical Properties of Thin Films, Applications of Thin Films in Devices |
| 21BPLXXXE | Open Elective – II | Elective | 3 | Topics vary based on chosen open elective from other departments, General courses from engineering, management, or humanities, Skill-based courses, Emerging technologies, Interdisciplinary applications |
| 21BPH703J | Project Work – Phase I | Project | 6 | Research Proposal Development, Extensive Literature Review, Methodology Design, Initial Experimental Work, Progress Report and Presentation |
Semester 8
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| 21BPH606E | Elective – IV (e.g., Nano Photonics) | Elective | 3 | Light-Matter Interaction at Nanoscale, Plasmonics and Metamaterials, Optical Nanodevices, Quantum Optics, Photonic Crystals |
| 21BPH609E | Elective – V (e.g., Computational Materials Science) | Elective | 3 | Density Functional Theory (DFT), Molecular Dynamics Simulations, Monte Carlo Methods in Materials, Computational Material Design, First-Principles Calculations |
| 21BPH801J | Project Work – Phase II | Project | 10 | Experimental Execution and Refinement, Advanced Data Analysis and Interpretation, Thesis Writing and Documentation, Oral Defense and Presentation, Potential for Publication/Patent |
