11.03.04 Electronics and Nanoelectronics

The "Microelectronics and Nanoelectronics" profile offers a comprehensive education in the cutting-edge field of microelectronics, preparing graduates for a future at the forefront of technological advancement.

This program focuses on the design, production, and application of a wide range of semiconductor devices, including:

• Integrated Circuits (ICs): Develop the tiny chips that power everything from smartphones to spacecraft.
• Single-Chip Computers: Design and implement powerful computing systems on a single chip, driving innovation in embedded systems and artificial intelligence.
• Communication Systems: Contribute to the design and implementation of advanced communication networks, shaping the future of wireless communication and internet connectivity.
• Consumer Electronics: Develop the electronics that power our daily lives, from smartphones and tablets to wearables and smart home devices.
• Medical Equipment: Design and develop innovative medical devices and systems, advancing healthcare technology and improving patient outcomes.

This program provides a strong foundation in:

• Fundamental Theoretical and Technical Knowledge: Master the principles of microelectronics, semiconductor physics, and device design.
• Advanced Computer Science and Information Technology: Gain expertise in programming, data analysis, and the use of computer-aided design (CAD) tools essential for modern microelectronics design.
• Modern Design and Modeling Techniques: Develop proficiency in using industry-standard CAD systems, such as CADENCE and Sentaurus TCAD, to simulate and optimize microelectronic devices and processes.

To further enhance the skillsets of the industry, the Novosibirsk Semiconductor Devices Plant has partnered with NSTU to establish a training class dedicated to mastering CADENCE and Sentaurus TCAD. This program fosters collaboration and prepares professionals to contribute to the development of leading-edge microelectronic technologies.

• Information technologies in professional activity
• Information technologies and programming basics
• Quantum and optical electronics
• Quantum mechanics and statistical physics
• Components of electronic equipment
• Materials science of nanostructured materials
• Materials and Methods of Nanotechnology
• Materials of microsystems technology
• Materials of electronic engineering
• Methods of analysis and control of nanostructured materials and systems
• Methods of mathematical modeling
• Methods of mathematical physics
• Metrology, standardization and certification
• Microprocessor devices
• Microelectromechanics
• Fundamentals of design and production technology of electronic devices
• Fundamentals of electronic component base design
• Software tools of professional activity
• Design activity
• Special chapters of solid state electronics
• Circuit engineering
• Solid State Electronics
• Technology of micro- and nanosystems components
• Condensed State Physics
• Semiconductor Physics
• Physics of semiconductor devices
• Physico-chemical bases of micro- and nanotechnology processes
• Physical bases of micro- and nanosystems technology
• Digital signal processing
• Elements and devices of nanoelectronics