Find information on common issues.
Ask questions and find answers from other users.
Suggest a new site feature or improvement.
Check on status of your tickets.
Electro-magnetics is one of the four fundamental interactions of nature, along with strong interaction, weak interaction and gravitation. It is the force that causes the interaction between electrically charged particles; the areas in which this happens are called electromagnetic fields.
Learn more about quantum dots from the many resources on this site, listed below. More information on Electromagnetism can be found here.
Object Oriented MicroMagnetic Framework (OOMMF) Example Notebooks
12 Dec 2017 | Tools
Least-Squares Finite Element Method and Nested Iteration for Electromagnetic Two-Fluid Plasma Models
04 Feb 2016 | Online Presentations | Contributor(s): Christopher Leibs
Efforts are currently being directed towards a fully implicit, electromagnetic, JFNK-based solver, motivating the necessity of developing a fluid-based, electromagnetic, preconditioning strategy...
Application of Multigrid Techniques to Magnetic and Electromagnetic Systems
04 Feb 2016 | Online Presentations | Contributor(s): Benjamin Cowan
We discuss the use of multigrid techniques for several novel systems related to electromagnetics. One of these is the magnetostatic problem, in which systems can involve highly anisotropic and...
[Illinois] Signal Integrity and Power Integrity Based on Computational Electromagnetics
20 Jan 2015 | Online Presentations | Contributor(s): Li-Jun Jiang
Dr. Lijun Jiang received the Bachelor Degree in electrical engineering from the Beijing University of Aeronautics and Astronautics in 1993, the Master Degree from the Tsinghua University in 1996,...
PhotonicsPOS: Particle on Substrate
12 Jan 2015 | Tools | Contributor(s): Rohith Chandrasekar, Urcan Guler, Ludmila Prokopeva, Alexander V. Kildishev
Scattering solutions for a core-shell spherical particle on a planar lamellar substrate
Modeling of Optical Multilayers for Both Spectra and Admittance Loci
03 Nov 2014 | Tools | Contributor(s): Joel che email@example.com, kuo-ping chen
simulate spectra and admittance loci of multilayer structures
19 Oct 2012 | Tools | Contributor(s): Jing Ouyang, Xufeng Wang, Minghao Qi
Finite-Difference Time-Domain Simulations
Electric Charge, Field, Flux and Potential Formula Sheet
15 Feb 2010 | Presentation Materials | Contributor(s): David Alberto Saenz
This is a Formula Sheet designed for a Fields and waves course at The University of Texas at El Paso as a part of a program to uplift the education. The book "University Physics with Modern...
PhotonicsSHA-2D: Modeling of Single-Period Multilayer Optical Gratings and Metamaterials
21 Aug 2009 | Tools | Contributor(s): Xingjie Ni, Zhengtong Liu, Fan Gu, Marcos Gabriel Pacheco, Joshua Borneman, Alexander V. Kildishev
Frequency domain simulation of single-period multilayer gratings and optical metamaterials upon TE/TM plane-wave incidence at arbitrary angles
Nano-Plasmonic Bowtie Antenna Simulator
15 Dec 2008 | Tools | Contributor(s): Alexander S McLeod, Jeffrey B. Neaton, P. James Schuck, Eugene Song, Graham Chapman
A tool for simulating the near-field enhancement effects of nano-scale bowtie antennae.
Hyperlens Design Solver
28 Jul 2008 | Tools | Contributor(s): Matt Swanson, Xingjie Ni, zubin jacob, Alexander V. Kildishev
Simulates a cylindrical hyperlens design to obtain resulting field intensities
90 Degrees Beam Propagation
24 Jun 2008 | Tools | Contributor(s): Carlos Montalvo, Derrick Kearney, Jing Ouyang, Minghao Qi
Calculation of beam propagation in dielectric waveguides
Metamaterials: A New Paradigm of Physics and Engineering
0.0 out of 5 stars
01 May 2008 | Courses | Contributor(s): Vladimir M. Shalaev
Three part lecture on metamaterials. Metamaterials are expected to open a gateway to unprecedented electromagnetic properties and functionality unattainable from naturally occurring materials,...
Nanosphere Optics Lab
31 May 2006 | Tools | Contributor(s): Jon Camden, George C. Schatz
Optical properties of nanospheres suspended in water, air, or other solutions
20 Apr 2006 | Tools | Contributor(s): Gang Li, Narayan Aluru
Computes the surface charge density distribution on the surface of the conductors in a multiconductor system