With just a few lines of mBuild code, you can assemble reusable components into complex molecular systems for molecular dynamics simulations.
- mBuild is designed to minimize or even eliminate the need to explicitly translate and orient components when building systems: you simply tell it to connect two pieces!
- mBuild keeps track of the system's topology so you don't have to worry about manually defining bonds when constructing chemically bonded structures from smaller components.
To learn more, get started or contribute, check out our website.
The mBuild
package is part of the Molecular Simulation Design Framework (MoSDeF) project.
Libraries in the MoSDeF ecosystem are designed to provide utilities neccessary to streamline
a researcher's simulation workflow. When setting up simulation studies,
we also recommend users to follow the TRUE
(Transparent, Reproducible, Usable-by-others, and Extensible) standard, which is a set of common
practices meant to improve the reproducibility of computational simulation research.
For full, detailed instructions, refer to the documentation for installation
mBuild
is available on conda
and can be installed as:
conda install -c conda-forge mbuild
Dependencies of mBuild are listed in the files environment.yml
(lightweight environment specification containing minimal dependencies) and environment-dev.yml
(comprehensive environment specification including optional and testing packages for developers).
The mbuild
or mbuild-dev
conda environments can be created with
git clone https://github.com/mosdef-hub/mbuild.git
cd mbuild
# for mbuild conda environment
conda env create -f environment.yml
conda activate mbuild
# for mbuild-dev
conda env create -f environment-dev.yml
conda activate mbuild-dev
# install a non-editable version of mbuild
pip install .
Once all dependencies have been installed and the conda
environment has been created, the mBuild
itself can be installed.
cd mbuild
conda activate mbuild-dev # or mbuild depending on your installation
pip install -e .
To use mbuild
in a jupyter-notebook that runs from a docker container with all the dependencies installed use the following command:
$ docker pull mosdef/mbuild:latest
$ docker run -it --name mbuild -p 8888:8888 mosdef/mbuild:latest su anaconda -s\
/bin/sh -l -c "jupyter-notebook --no-browser --ip="0.0.0.0" --notebook-dir\
/home/anaconda/mbuild-notebooks
Alternatively, you can also start a Bourne shell directly:
$ docker run -it --name mbuild mosdef/mbuild:latest
To learn more about using mBuild
with docker, please refer to the documentation here.
Interactive tutorials can be found here:
Components in dashed boxes are drawn by hand using, e.g., Avogadro or generated elsewhere. Each component is wrapped as a simple python class with user defined attachment sites, or ports. That's the "hard" part! Now mBuild can do the rest. Each component further down the hierarchy is, again, a simple python class that describes which piece should connect to which piece.
Ultimately, complex structures can be created with just a line or two of code. Additionally, this approach seamlessly exposes tunable parameters within the hierarchy so you can actually create whole families of structures simply by adjusting a variable:
import mbuild as mb
from mbuild.examples import PMPCLayer
pattern = mb.Random2DPattern(20) # A random arrangement of 20 pieces on a 2D surface.
pmpc_layer = PMPCLayer(chain_length=20, pattern=pattern, tile_x=3, tile_y=2)
Use case-specific systems can be generated via mBuild recipes. Some users have graciously contributed recipes for particular systems, including:
If you use this package, please cite our paper. The BibTeX reference is
@article{Klein2016mBuild,
author = "Klein, Christoph and Sallai, János and Jones, Trevor J. and Iacovella, Christopher R. and McCabe, Clare and Cummings, Peter T.",
title = "A Hierarchical, Component Based Approach to Screening Properties of Soft Matter",
booktitle = "Foundations of Molecular Modeling and Simulation",
series = "Molecular Modeling and Simulation: Applications and Perspectives",
year = "2016",
doi = "http://dx.doi.org/10.1007/978-981-10-1128-3_5"
}
Various sub-portions of this library may be independently distributed under different licenses. See those files for their specific terms.
This material is based upon work supported by the National Science Foundation under grants NSF CBET-1028374 and NSF ACI-1047828. Any opinions, findings, and conclusions or recommendations expressed in this material are those of the author(s) and do not necessarily reflect the views of the National Science Foundation.