NAMD, recipient of a 2002 Gordon Bell Award, a 2012 Sidney Fernbach Award, and a 2020 Gordon Bell Prize, 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 cores for typical simulations and beyond 500,000 cores for the largest simulations. 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.
Breaking News
NAMD 3.0b7 Release - GPU-resident mode now calculates meaningful averages for energy, temperature, and pressure. Improves HIP performance. Fixes use of GPU atom migration with advanced features. Supports vdW force switching for GPU-based alchemy. Fixes some race conditions and calculation issues for GPU-based alchemy. |
NAMD 3.0 New Features - webpage is posted |
NAMD GPU-resident benchmarks - results and data sets with GPU-optimized configuration posted |
NAMD 3.0b6 Release - fixes important bugs from last two beta releases |
NAMD 2.15 ALPHA Release providing GPU-offload support for Intel GPU Max Series. This source code release available on the download page includes SYCL code that can be built using the Intel oneAPI toolkits. Following the download link reveals a page with detailed build instructions. |
Spotlight: How Cells "Feel" Mechanical Tension and Osmotic Stress (May 2001)
image size:
247.9KB
made with VMD
"How do you feel?" Biologists now have an answer that may surprise you. Our sense of touch relies upon the fact that cells in our fingertips can sense the pressure from a tabletop and transmit a signal to the brain. But until recently, the molecular mechanism for turning the stretching of a cell membrane into a cellular signal was unknown. An important step in understanding this process was the discovery of a protein known as a the mechanosensitive channel of large conductance, or MscL. Though this protein has been studied primarily in bacteria, homologues exist in all major kingdoms of life. Researchers in the Theoretical Biophysics Group have used molecular dynamics simulations to study, at the atomic level, how MscL opens in response to pressure changes. Models of MscL will give us new insight, not only into how we feel, but also how our hearts beat and how we keep our balance. Feel better now? ( more, publication )
Overview
Why NAMD? (in pictures)
How to Cite NAMD
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
- Git access now available
Run at NCSA, SDSC, NICS, or Texas
Training
NAMD Developer Workshop in Urbana (August 19-20, 2019)
PRACE School on HPC for Life Sciences (June 10-13, 2019)
"Hands-On" Workshop in Pittsburgh (May 13-17, 2019)
Charm++ Workshop in Urbana (May 1-2, 2019)
Enhanced Sampling and Free-Energy Workshop (Sept 10-14, 2018)
NAMD Developer Workshop in Urbana (June 11-12, 2018)
"Hands-On" Workshop in Pittsburgh (May 21-25, 2018)
"Hands-On" QM/MM Simulation Workshop (April 5-7, 2018)
Older "Hands-On" Workshops
Support
Mailing List Issues for Yahoo.com Addresses
Announcements
NAMD 3.0b7 Release (May 2024)NAMD 3.0b6 Release (Feb 2024)
NAMD 3.0 New Features (Feb 2024)
NAMD 2.14 Bug Fixes (Apr 2022)
NAMD 2.14 Release (Aug 2020)
NAMD 2.14 New Features
One-click NAMD/VMD in the cloud
QM/MM Interface to MOPAC and ORCA
QwikMD GUI Released in VMD 1.9.3
Previous Announcements
Documentation
Related Codes, Scripts, and Examples
NAMD Wiki (Recent Changes)
Older Documentation
News
AMBER force field use in NAMD for large scale simulation
NAMD GPU-resident benchmarks available
NAMD and VMD share in COVID-19 Gordon Bell Special Prize
NAMD reference paper published online
Coronavirus Simulations by U. Delaware Team
Coronavirus Simulations on Frontera Supercomputer
Breakthrough Flu Simulations
Oak Ridge Exascale Readiness Program
Prepping for Next-Generation Cray at NERSC
Supercomputing HIV-1 Replication
How GPUs help in the fight against staph infections
Computational Microscope Gets Subatomic Resolution
Opening New Frontiers in the Battle Against HIV/AIDS
HIV Capsid Interacting with Environment
Assembling Life's Molecular Motor
Older News Items