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On June 30, 1948, AT&T Bell Labs unveiled the transitor to the world, creating a spark of explosive economic growth that would lead into the Information Age. William Shockley led a team of researchers, including Walter Brattain and John Bardeen, who invented the device. Like the existing triode vacuum tube device, the transistor could amplify signals and switch currents on and off, but the transistor was smaller, cheaper, and more efficient. Moreover, it could be integrated with millions of other transistors onto a single chip, creating the integrated circuit at the heart of modern computers.
Today, most transistors are being manufactured with a minimum feature size of 60-90nm--roughly 200-300 atoms. As the push continues to make devices even smaller, researchers must account for quantum mechanical effects in the device behavior. With fewer and fewer atoms, the positions of impurities and other irregularities begin to matter, and device reliability becomes an issue. So rather than shrink existing devices, many researchers are working on entirely new devices, based on carbon nanotubes, spintronics,
molecular conduction, and other nanotechnologies.
Learn more about transistors from the many resources on this site, listed below. Use our simulation tools to simulate performance characteristics for your own devices.
Illinois ECE 440 Solid State Electronic Devices, Lectures 8 and 9: Drift Mobility
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30 Sep 2009 | Online Presentations | Contributor(s): Eric Pop
Carrier Mobility and Drift
ECE 440: Lectures 8-9
Carrier Mobility and Drift
Let’s recap the 5-6 major concepts so far:
Memorize a few things, but recognize many.
Lecture 5: NEGF Simulation of Graphene Nanodevices
23 Sep 2009 | Online Presentations | Contributor(s): Supriyo Datta
Network for Computational Nanotechnology,
Lecture 1: Percolation and Reliability of Electronic Devices
17 Sep 2009 | Online Presentations | Contributor(s): Muhammad A. Alam
Illinois ECE 440 Solid State Electronic Devices, Lecture 5: Intrinsic Material, Doping, Carrier Concentrations
03 Aug 2009 | Online Presentations | Contributor(s): Eric Pop, Omar Sobh
University of Illinois at Urbana-Champaign ECE 440: Solid State Electronic Devices
Illinois ECE 440 Solid State Electronic Devices, Lecture 5, Part 2 : Doping, Carrier Concentrations
ECE 606 Lecture 40: Looking Back and Looking Forward
30 Apr 2009 | Online Presentations
ECE 606 Lecture 37b: Nonideal Effects in MOSFET II
28 Apr 2009 | Online Presentations | Contributor(s): Muhammad A. Alam
ECE 606 Lecture 36: MOSFET I-V Characteristics II
ECE 606 Lecture 37a: Nonideal Effects in MOSFET I
ECE 606 Lecture 39: Reliability of MOSFET
ECE 606 Lecture 33: MOS Electrostatics II
16 Apr 2009 | Online Presentations | Contributor(s): Muhammad A. Alam
ECE 606 Lecture 34: MOSCAP Frequency Response
ECE 606 Lecture 35: MOSFET I-V Characteristics I
ECE 606 Lecture 30: Heterojunction Bipolar Transistors I
04 Apr 2009 | Online Presentations | Contributor(s): Muhammad A. Alam
ECE 606 Lecture 31: Heterojunction Bipolar Transistors II
ECE 606 Lecture 29: BJT Design II
31 Mar 2009 | Online Presentations | Contributor(s): Muhammad A. Alam
ECE 606 Lecture 19: Numerical Solution of Transport Equation
29 Mar 2009 | Online Presentations | Contributor(s): Muhammad A. Alam
Basic Transport Equations
Gridding and finite differences
Discretizing equations and boundary conditions
Lundstrom, Mark, A Primer on Semiconductor Device Simulation,...
ECE 606 Lecture 28: BJT Design I
ECE 606 Lecture 27: Introduction to Bipolar Transistors
ECE 606 Lecture 25: Schottky Diode I
24 Mar 2009 | Online Presentations | Contributor(s): Muhammad A. Alam