1 / 19

Advanced Program in Microelectronic Devices, Electromagnetics, Plasma Physics, & Photonics

This program offers a comprehensive curriculum in the fields of microelectronic devices, electromagnetics, plasma physics, and photonics. It covers a range of topics including circuit design, semiconductor devices, optics, and plasma physics. The program provides a strong foundation in these areas, preparing students for careers in various industries.

armandon
Download Presentation

Advanced Program in Microelectronic Devices, Electromagnetics, Plasma Physics, & Photonics

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Microelectronic Devices, Electromagnetics, Plasma Physics, & PhotonicsProf. James Teheranij.teherani@columbia.edu

  2. Approaches to program • All of these topics are closely related, so the best program will likely mix and match topics to suit your interests • There are introductory courses offered in the fall in all of the topical areas if you are still deciding • Note that some of the relevant courses are offered in other departments in SEAS

  3. Circuit design A billion devices One device Materials/one atom Physics + math

  4. How do we get from Intel Core M Processor 1.3B transistors

  5. Microelectronic devices • Covers: • Fabricating devices starting from raw materials • Modeling, and understanding their operation (especially the physics of operation) • Design of superior devices • Use at the single device level (circuit design is at the multi-device level) • Useful for careers in silicon microelectronics, MEMS, device modeling, solar energy, and device/material fabrication. • Device physics is foundational for circuit design

  6. Microelectronics-Fall ELEN 4301 Introduction to Semiconductor Devices ELEN 4944 Principles of Microfabrication ELEN 6907 Emerging NanoelectronicDevices MECE 4212 Microelectromechanical Systems Courses in solid state physics/material science: APPH 4100 Quantum Physics of Matter APPH 6081 Solid State Physics, I CHAP 4120 Statistical Mechanics MSAE 4206 Electronic and Magnetic Properties of Solids

  7. Microelectronics-Spring ELEN 4301 Introduction to Semiconductor Devices (new class now offered in Fall) ELEN 6331 Principles of Semiconductor Physics APPH 6082 Solid State Physics, II MECE 4212 Microelectromechanical Systems MECE 4213 Bio-microelectromechanical Systems (BioMEMS): Design, Fabrication and Analysis + more… More courses will be offered in the spring in all topical areas, but their schedules are not finalized.

  8. Optics and Electromagnetics • Making devices that generate, measure, or manipulate light and radio waves • Using them to do useful things (e.g. building high speed networks) • Useful for many careers in science and engineering. Topics include networking, surface science, optoelectronics device fabrication, displays, data storage, and laser technology. • Also relevant for optical and RF circuit design

  9. Optics Fall: ELEN 4193 Display Science and Technology ELEN 4411 Fundamentals of Photonics APPH 4110 Modern Optics ELEN 6413 LightwaveSystems ELEN 4488 Optical Systems Spring: ELEN 6412 LightwaveDevices ELEN 6488 Optical Interconnects + Interconnection Networks

  10. Electromagnetics Fall: ELEN 4411 Fundamentals of Photonics APPH 4300 Applied Electrodynamics BMEN 4430 Principles of Magnetic Resonance imaging Spring: ELEN 4703 Wireless Communications

  11. Plasma physics (APAM) • How to understand, make, and control plasmas (overlaps with electromagnetism and many other traditional EE areas) • Extensively used in some areas of lighting, fusion, material conversion, material analysis, plasma fusion, astrophysics, etc. Fall • APPH 6101 Plasma Physics, I Spring • APPH 4301 Introduction To Plasma Physics (pre-req for other courses in the area) • APPH 6102 Plasma Physics, II

  12. Other relevant classes APPH 4130 Physics of Solar Energy MECE 4210 Energy Infrastructure Planning Classes in medical and nuclear physics

  13. Final advice • The devices/optics/electromag. track offers a variety of choices for concentration or to enrich a program in another area (e.g. circuits) • Assess your mastery of the prerequisites for each track you’re interested in and make sure to take a course that’s at the right level for you • Be sure to keep courses in other related departments in mind when mapping out your schedule • Your career goals will help guide which areas you want to focus in • If you are interested in research, look for projects! Up to 6 units of project can be applied toward your degree. • Think about what you will do over the summer and after you graduate

  14. ELEN 4301Intro to Semiconductor Devices

  15. ELEN 4301Intro to Semiconductor Devices

  16. ELEN 4301Intro to Semiconductor Devices • New, revamped curriculum • MS/PhD students: great foundational course • PhD students: great to prepare for quals • Provides strong fundamentals,useful across diverse areas • Photonics • Analog + Digital Circuits • Microfabrication • VLSI design

  17. Download Presentation

More Related