NAMD, recipient of a 2002 Gordon Bell Award, is a parallel molecular dynamics code designed for high-performance simulation of large biomolecular systems. Based on Charm++ parallel objects, NAMD scales to hundreds of processors on high-end parallel platforms and tens of processors on commodity clusters using gigabit ethernet. NAMD uses the popular molecular graphics program VMD for simulation setup and trajectory analysis, but is also file-compatible with AMBER, CHARMM, and X-PLOR. NAMD is distributed free of charge with source code. You can build NAMD yourself or download binaries for a wide variety of platforms. Our tutorials show you how to use NAMD and VMD for biomolecular modeling.
The 2005 reference paper Scalable molecular dynamics with NAMD has over 1000 citations as of March 2010.
Spotlight: Computational Microscopy of the Ribosome (Nov 2010)
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140.2KB
made with VMD
The ribosome is a molecular machine ubiquitous in all living cells and translates genetic information into proteins. Proteins are made of twenty different amino acids, strung in a linear sequence. The amino acids are coded for by the genes in DNA, but for the purpose of protein synthesis genes are transcribed into a working copy, a messenger RNA. The latter is translated by the ribosome into proteins with the help of transfer RNAs, which bring the individual amino acids. There is a transfer RNA for each of the twenty amino acids. Much progress has been made regarding the static structure of the ribosome, transfer RNA, and nascent protein components (see also the Dec 2009 and Jan 2009 highlights Managing the Protein Assembly Line and Open Sesame). Now researchers are looking into the inner workings of the whole system combining various experiments and computational modeling using NAMD and VMD. The combination yielded unprecedented detailed views of the ribosome in action as reported recently, namely how a dynamic part of the ribosome helps guiding transfer RNAs on their way out of the ribosome, and explains why transfer RNAs behave differently on their journey, depending on if they start synthesis of a protein or if they elongate a protein. More on our ribosome website.
Overview
Having Problems with NAMD?
Why NAMD? (in pictures)
Steered Molecular Dynamics
Interactive Molecular Dynamics
Features and Capabilities
Performance Benchmarks
Publications and
Citations
Credits and Development Team
Availability
Read the License
Download NAMD Binaries
(also VMD)
Build from Source Code
Run at NCSA, SDSC, NICS, or Texas
Training
"Hands-On" Workshop in Urbana (Feb 11-15, 2012)
Online Workshop on Simulating Membrane Channels (Nov 28-Dec 1, 2011)
"Hands-On" Workshop in Bremen
(Oct 17-21, 2011)
Online Workshop on Simulating Membrane Channels (Aug 1-4, 2011)
In-Residence Training in Urbana
(July 25-Aug 5, 2011)
"Hands-On" Workshop in Pittsburgh (May 16-20, 2011)
Charm++ Workshop (April 18-20, 2011)
"Hands-On" Workshop in Atlanta (March 21-25, 2011)
GPU Programming Workshop in Urbana (Aug 7-8, 2010)
"Hands-On" Computational Biophysics Workshops
Older Workshops
Support
Announcements
2011 User Survey Report
NAMD 2.8 New Features
NAMD 2.8 (May 2011)
NAMD 2.7 New Features
NAMD 2.7 (Oct 2010)
How to Cite NAMD
Previous Announcements
Documentation
Adaptive Biasing Force Website
Interactive Molecular Dynamics Tutorial
Related Codes, Scripts, and Examples
NAMD Wiki (Recent Changes)
Older Documentation
News
Proteins Help DNA Replicate Past Damage
SC11: Scaling to 100 Million Atoms
Copper Folds Parkinson's Plaques
Mechanics of Membrane Proteins
Molecular Mystery of Blood Clotting
Alzheimer's Misfolding Simulated
When Cellular Bones Soften
Getting the Rabbit in the Hat
Insights Into Deafness
Molecular Machines Replicate and Repair DNA
Sound Science
Blueprint for the Affordable Genome
Mechanics of Hearing and Deafness
NAMD Paper Has 1000 Citations
Closing the Gaps
Inside the Swine Flu Virus
GPU Acceleration in Development
NCSA IACAT to Accelerate NAMD
Parkinson's, Alzheimer's Diseases
Knock, Knock, Who's There?
Step Up to the BAR Domain
Older News Items