Self Paced

Silicon Nanostructures and Carbon Nanotubes based Nanoelectronics

Exploring the Boundaries of Nanoelectronics: Harnessing Silicon Nanostructures and Carbon Nanotubes for Next-Generation Innovation

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Early access to the e-LMS platform is included

  • Mode: Online/ e-LMS
  • Type: Self Paced
  • Level: Moderate
  • Duration: 1 Month

About This Course

The Silicon Nanostructures and Carbon Nanotubes based Nanoelectronics program delves into the cutting-edge realm of nanoelectronics, focusing on harnessing the remarkable properties of silicon nanostructures and carbon nanotubes. By exploring these advanced materials at the nanoscale, the program aims to revolutionize electronic device design and functionality. Through innovative research and development efforts, the program seeks to pioneer next-generation electronic devices with superior performance, scalability, and energy efficiency. These advancements hold the potential to transform various sectors, from computing and communication to sensing and energy storage, ushering in a new era of nanoelectronics innovation.

Furthermore, the program is dedicated to fostering interdisciplinary collaboration and knowledge exchange among scientists, engineers, and industry partners. By cultivating a collaborative research environment, the program aims to accelerate the translation of fundamental discoveries into practical applications, driving technological innovation and economic growth. Through strategic partnerships and collaborative initiatives, the program seeks to address key challenges in nanoelectronics research and development, paving the way for transformative advancements that will shape the future of electronic devices and technologies.

Aim

The aim of the “Silicon Nanostructures and Carbon Nanotubes based Nanoelectronics” program is to advance the frontier of nanoelectronics by leveraging the unique properties of silicon nanostructures and carbon nanotubes, aiming to develop innovative electronic devices and technologies with enhanced performance, scalability, and energy efficiency for various applications ranging from computing and communication to sensing and energy storage.

Program Objectives

  • Understand the fundamental properties and synthesis methods of silicon nanostructures and carbon nanotubes.
  • Apply nanomaterials to develop innovative electronic devices.
  • Master the techniques of integrating nanostructures into existing semiconductor technologies.
  • Analyze the performance enhancements brought by nanostructures in electronics.
  • Prepare for leadership roles in the technology sector by adopting advanced nanotechnology practices.

Program Structure

  • Semiconductor Nanostructures & Nanomaterials
  • Semiconductor Nanostructures & Nanomaterials: Introduction
  • Silicon Nanowires
  • Silicon Quantum Dots
  • Silicon Nanotubes
  • Hybrid Silicon-Carbon Nanotubes
  • Silicon Carbide Nanotubes
  • Carbon Nanotube based Field Emission Devices
  • Carbon Nanotube Transistors
  • Single Electron Transistor
  • Ballistic Carbon Nanotube Field Effect Transistor with Palladium Contact
  • Overview of Carbon Nanotube Field Effect Transistor Technology
  • Notable Achievements in Nanoelectronics

Who Should Enrol?

  • M.Tech students specializing in Electrical Engineering, Nanotechnology, Material Science, or Semiconductor Technology.
  • M.Sc students in Physics, Chemistry, Material Science, or Electronic Engineering with a focus on nanoscale materials or devices.
  • E0 level professionals who are just beginning their careers in technology sectors such as semiconductor manufacturing, electronics design, or nanotech firms and are looking to enhance their skills with advanced materials.
  • E1 level professionals with some experience in industries such as electronic design automation, semiconductor manufacturing, or material research, aiming to deepen their knowledge and technical skills in nanostructured devices and integration techniques.

Program Outcomes

  • Advanced understanding of nanostructured materials
  • Proficiency in nanomaterials integration
  • Enhanced skills in electronics design
  • Expertise in semiconductor technologies
  • Capability to innovate in tech product development

Fee Structure

Standard: ₹4,998 | $110

Discounted: ₹2499 | $55

We accept 20+ global currencies. View list →

What You’ll Gain

  • Full access to e-LMS
  • Real-world dry lab projects
  • One-on-one project guidance
  • Publication opportunity
  • Self-assessment & final exam
  • e-Certificate & e-Marksheet

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