Tags: electrostatics

Online Presentations (1-20 of 21)

  1. ECE 595E Lecture 9: Programming for Linear Algebra

    01 Feb 2013 | | Contributor(s):: Peter Bermel

    Outline:Recap from FridayApplication ExamplesElectrostatic potential (Poisson’s equation)1D array of charge2D grid of chargeArrays of interacting spins1D interaction along a chain2D nearest-neighbor coupling

  2. ECE 606 Lecture 21: MOS Electrostatics

    26 Nov 2012 | | Contributor(s):: Gerhard Klimeck

  3. ECE 606 Lecture 16: p-n Diode AC Response

    24 Oct 2012 | | Contributor(s):: Gerhard Klimeck

  4. ECE 606 Lecture 15: p-n Diode Characteristics

    17 Oct 2012 | | Contributor(s):: Gerhard Klimeck

  5. ECE 606 Lecture 14: p-n Junctions

    04 Oct 2012 | | Contributor(s):: Gerhard Klimeck

  6. Nanoscale Transistors Lecture 4: MOS Electrostatics

    19 Jul 2012 | | Contributor(s):: Mark Lundstrom

  7. Particle Simulations of Ion Generation and Transport in Microelectromechanical Systems and Micropropulsion

    29 May 2012 | | Contributor(s):: Venkattraman Ayyaswamy

    The first part of the talk deals with use of the PIC method with Monte Carlo collisions (MCC) between electrons and the ambient neutral gas to develop models to predict charge accumulation, breakdown voltage, etc. for various ambient gases, gap sizes, cathode material, and frequency of applied...

  8. 2010 Nano-Biophotonics Summer School @ UIUC Lecture 2 - 2D/3D Fourier transforms & Electromagnetic fields/ Lorentz-Drude model

    25 Sep 2010 | | Contributor(s):: Gabriel Popescu

    So far, we have discussed Fourier transformations involving one-dimensional functions. Of course, in studying imaging, the conceptmust be generalized to 2D and 3D functions. For example, diffraction and 2D image formation are treated efficiently via 2D Fouriertransforms, while light scattering...

  9. ME 597 Lecture 25: Using the AFM to Measure Electrostatic Forces

    02 Dec 2009 | | Contributor(s):: Ron Reifenberger

  10. Illinois ECE 440 Solid State Electronic Devices, Lecture 18: P-N Diode Electrostatics

    22 Oct 2009 | | Contributor(s):: Eric Pop

    Last time, we talked about p-n junction built-in voltage V¬0.Today: more about p-n electrostatics.

  11. ECE 606 Lecture 33: MOS Electrostatics II

    16 Apr 2009 | | Contributor(s):: Muhammad A. Alam

  12. ECE 606 Lecture 20: Electrostatics of P-N Junction Diodes

    11 Mar 2009 | | Contributor(s):: Muhammad A. Alam

  13. ECE 612 Lecture 25: SOI Electrostatics

    08 Dec 2008 | | Contributor(s):: Mark Lundstrom

    Outline:1. Introduction,2. General solution, 3. VTF vs. VGB,4. Subthreshold slope,5. Double gate (DG) SOI,6. Recap,7. Discussion,8. Summary.

  14. ECE 606 Lecture 32: MOS Electrostatics I

    19 Nov 2008 | | Contributor(s):: Muhammad A. Alam

  15. MSE 597G Lecture 5: Interatomic potentials II

    13 Nov 2008 | | Contributor(s):: Alejandro Strachan

    Embedded atom model for metals,Three body terms for semiconductors: Stillinger-Weber,Electrostatics and Covalent interactions.

  16. ECE 612 Lecture 14: VT Engineering

    28 Oct 2008 | | Contributor(s):: Mark Lundstrom

    Outline: 1) VT Specification,2) Uniform Doping,3) Delta-function doping, xC = 0,4) Delta-function doping, xC > 0,5) Stepwise uniform,6) Integral solution.The doping profiles in modern MOSFETs are complex. Our goal is to develop an intuitive understanding of how non-uniform doping profiles affect...

  17. ECE 612 Lecture 12: 2D Electrostatics

    28 Oct 2008 | | Contributor(s):: Mark Lundstrom

    Outline:1) Consequences of 2D electrostatics,2) 2D Poisson equation,3) Charge sharing model,4) Barrier lowering,5) 2D capacitor model,6) Geometric screening length,7) Discussion,8) Summary.

  18. ECE 495N Lecture 5: Quantitative Model for Nanodevices II

    12 Sep 2008 | | Contributor(s):: Supriyo Datta

  19. ECE 495N Lecture 3: Importance of Electrostatics

    10 Sep 2008 | | Contributor(s):: Supriyo Datta

  20. ECE 612 Lecture 2: 1D MOS Electrostatics II

    09 Sep 2008 | | Contributor(s):: Mark Lundstrom

    Outline: 1) Review,2) ‘Exact’ solution (bulk), 3) Approximate solution (bulk), 4) Approximate solution (ultra-thin body), 5) Summary.