The Master of Science (M.Sc.) in Nanotechnology program is an interdisciplinary and cutting-edge graduate program designed to provide students with a comprehensive understanding of nanoscience and nanotechnology, preparing them for careers in research, development, and application of nanoscale materials and devices. The course syllabus typically spans two academic years, offering a diverse range of subjects that bridge the gap between various scientific disciplines. The program begins with foundational courses in Nanoscience and Nanotechnology, covering the principles of nanomaterials, nanofabrication techniques, and the unique properties exhibited by materials at the nanoscale. Students explore topics in Quantum Mechanics and Solid-State Physics, gaining insights into the behavior of particles at the atomic and molecular levels, which is fundamental to understanding nanoscale phenomena. As the program progresses, students delve into specialized areas, including Nanomaterials Synthesis and Characterization, where they learn how to create and analyze nanomaterials with desired properties. Nanoelectronics and Nanophotonics courses explore the design and application of nanoscale electronic and photonic devices, while Nanobiotechnology delves into the interface between nanotechnology and biology, addressing applications in drug delivery, diagnostics, and tissue engineering. Nanomaterials for Energy and Environmental Applications tackle the use of nanotechnology in sustainable energy generation, storage, and environmental remediation.
Advanced coursework often includes Nanomechanics and Nanotribology, focusing on the mechanical properties and friction at the nanoscale. Additionally, courses on Nanofluidics and Microfluidics examine fluid flow behavior in micro and nanoscale systems, which is vital in fields like lab-on-a-chip technology and biotechnology.In most programs, students have the opportunity to choose elective courses tailored to their interests and career goals, such as courses in Nanomedicine, Nanoscale Sensors, or Nanomaterials for Electronics. These electives allow students to deepen their knowledge in specific areas of nanotechnology.
Laboratory work is a central component of the M.Sc. in Nanotechnology, where students gain hands-on experience in nanofabrication, materials characterization, and experimental techniques used in nanoscience research. These practical experiences are essential for students to develop the skills necessary for conducting research and innovation at the nanoscale. many programs require students to complete a research project or thesis in collaboration with faculty or industry partners. This project allows students to contribute to ongoing nanotechnology research and explore their own research interests under the guidance of experienced researchers.
1st Year OR 1st & 2nd Semester Syllabus of Master of Science (M.Sc.) Nanotechnology
S.no | Subjects |
1 | Intro to Basic Science |
2 | Introduction to Nanoscience and Nanotechnology |
3 | Introduction to Material Science |
4 | Preparation of Nanomaterials |
5 | Properties of Nanomaterials |
6 | Introduction to Nanobiotechnology |
7 | Introduction to Nanotoxicology |
2nd Year OR 3rd & 4th Semester Syllabus of Master of Science (M.Sc.) Nanotechnology
S.No | Subjects |
1 | Nanoelectronics and Nanosensors |
2 | Nanomaterials for Energy System |
3 | Applications of Nanomaterials |
4 | Advanced Nanobiotechnology |
5 | Biomedical Nanotechnology |
6 | Computational Nanoscience |
7 | Project Work |