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description
Closed | Responses: 1
please help me by giving a detailed idea on fermi level..do suggest some reference online sites for further guidance????
http://nanohub.org/answers/question/945
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Where is fermi level located in bandgap of Carbon Nanotube ?
Closed | Responses: 0
It is well known that a Schottky barrier is formed at Metal-Nanotube junction. To draw band diagram of Metal-CNT system, Band diagram of Carbon Nanotube in vaccume should be known. When both...
http://nanohub.org/answers/question/11
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Why is Fermi level always constant in an equilibrium problem?
Open | Responses: 1
I find it difficult to visualize (or concretely understand) the fact that Fermi level should universally stay constant in an equilibrium between different materials.
I have seen this so many...
http://nanohub.org/answers/question/35
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ABACUS - Assembly of Basic Applications for Coordinated Understanding of Semiconductors
16 Jul 2008 | | Contributor(s):: Xufeng Wang, Dragica Vasileska, Gerhard Klimeck
One-stop-shop for teaching semiconductor device education
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ABACUS—Introduction to Semiconductor Devices
When we hear the term semiconductor device, we may think first of the transistors in PCs or video game consoles, but transistors are the basic component in all of the electronic devices we use in...
http://nanohub.org/wiki/EduSemiconductor
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BJT Lab
06 Feb 2008 | | Contributor(s):: Saumitra Raj Mehrotra, Abhijeet Paul, Gerhard Klimeck, Dragica Vasileska, Gloria Wahyu Budiman
This tool simulates a Bipolar Junction Transistor (BJT) using a 2D mesh. Powered by PADRE.
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Carrier Statistics Lab Video Demonstration
21 Sep 2010 | | Contributor(s):: Saumitra Raj Mehrotra
This video shows: Basic input deck for the tool,Simulation run of Temperature sweep with constant fermi level, Simulation run of Temperature sweep with constant doping.
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Discussion Session 1 (Lectures 1a, 1b and 2)
08 Sep 2010 | | Contributor(s):: Supriyo Datta
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ECE 606 Lecture 13a: Fermi Level Differences for Metals and Semiconductors
16 Feb 2009 | | Contributor(s):: Muhammad A. Alam
Short chalkboard lecture on Fermi level and band diagram differences for metals and semiconductors.
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ECE 656 Lecture 12: Scattering and Transmission
21 Sep 2011 | | Contributor(s):: Mark Lundstrom
Outline:IntroductionPhysics of carrier scatteringTransmission and mfpMFP and scatteringDiscussionSummary
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Exercise: MATLAB Tool Construction for Degenerate/Nondegenerate Semiconductors That Includes Partial Ionization of the Dopants
29 Jul 2008 | | Contributor(s):: Dragica Vasileska, Gerhard Klimeck
This exercise teaches the students how to calculate Ec-Ef from charge neutrality for general Fermi-Dirac statistics and compensated semiconductors. As such it then allows the student to calculate temperature dependence of the electron and hole densities as well as the position of the Fermi...
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Illinois ECE 440 Solid State Electronic Devices, Lecture 12: Quasi-Fermi Levels; Photoconductivity
05 Jan 2009 | | Contributor(s):: Eric Pop
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Illinois ECE 440 Solid State Electronic Devices, Lecture 6: Doping, Fermi Level, Density of States
04 Dec 2008 | | Contributor(s):: Eric Pop, Umair Irfan
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Lecture 1b: Nanotransistors - A Bottom Up View
19 Jul 2010 | | Contributor(s):: Mark Lundstrom
MOSFET scaling continues to take transistors to smaller and smaller dimensions. Today, the MOSFET is a true nanoelectronic device – one of enormous importance for computing, data storage, and for communications. In this lecture, I will present a simple, physical model for the nanoscale MOSFET...
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Semiconductor Device Education Material
28 Jan 2008 | | Contributor(s):: Gerhard Klimeck
This page has moved to "a Wiki page format" When we hear the words, semiconductor device, we may think first of the transistors in PCs or video game consoles, but transistors are the basic component in all of the electronic devices we use in our daily lives. Electronic systems are...
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Thermoelectric Power Factor Calculator for Superlattices
18 Oct 2008 | | Contributor(s):: Terence Musho, Greg Walker
Quantum Simulation of the Seebeck Coefficient and Electrical Conductivity in 1D Superlattice Structures using Non-Equilibrium Green's Functions