Octahedral distortion calculator: A tool for calculating distortion parameters in coordination complexes. https://octadist.github.io/
OctaDist is computer software for inorganic chemistry and crystallography program. OctaDist can be used for studying the structural distortion in coordination complexes. With the abilities of OctaDist, you can:
- analyze the structure and conformation of coordination complexes.
- compute the octahedral distortion parameters.
- explore tilting distortion in perovskite and metal-organic framework.
- display 3D molecule for graphical analysis.
- implement OctaDist's module into your or other program.
- access the program core directly via an interactive scripting language.
User manual: https://octadist.github.io/manual.html.
Reference manual :
Version | Status | Docs |
---|---|---|
Latest | HTML / PDF / Epub | |
Dev Build | HTML / PDF / Epub |
For Windows users, we strongly suggest a standalone executable:
Click Here to Download OctaDist-3.1.0-Win-x86-64.exe (389 MB)
For Linux or macOS users and already have Python 3 installed on the system,
the easiest way to install OctaDist is to use pip
.
Note that OctaDist supports up to Python 3.9.
pip install octadist
or use conda
for those who have Anaconda:
conda install -c rangsiman octadist
The following commands can be used to start OctaDist in different ways:
To start GUI program:
octadist
Screenshots of program:
OctaDist GUI | XYZ coordinates | Computed distortion parameters |
To start program command line:
octadist_cli
To calculate distortion parameters:
octadist_cli --inp EXAMPLE_INPUT.xyz
To calculate distortion parameters and show formatted output:
octadist_cli --inp EXAMPLE_INPUT.xyz --format
import octadist as oc
# Prepare list of atomic coordinates of octahedral structure:
atom = ['Fe', 'O', 'O', 'N', 'N', 'N', 'N']
coord = [
[2.298354000, 5.161785000, 7.971898000], # <- Metal atom
[1.885657000, 4.804777000, 6.183726000],
[1.747515000, 6.960963000, 7.932784000],
[4.094380000, 5.807257000, 7.588689500],
[0.539005000, 4.482809500, 8.460004000],
[2.812425000, 3.266553000, 8.131637000],
[2.886404000, 5.392925000, 9.848966000],
]
dist = oc.CalcDistortion(coord)
zeta = dist.zeta # 0.228072561
delta = dist.delta # 0.000476251
sigma = dist.sigma # 47.92652837
theta = dist.theta # 122.6889727
import os
import octadist as oc
# You can also import your input file, like this:
file = "Multiple-metals.xyz"
# Then use coord.extract_file to extract all atomic symbols and coordinates,
# and then use coord.extract_octa for taking the octahedral structure.
atom_full, coord_full = oc.io.extract_coord(file)
atom, coord = oc.io.extract_octa(atom_full, coord_full)
dist = oc.CalcDistortion(coord)
zeta = dist.zeta # 0.0030146365519487794
delta = dist.delta # 1.3695007180404868e-07
sigma = dist.sigma # 147.3168033970211
theta = dist.theta # 520.6407679851042
import os
import octadist as oc
file = "Multiple-metals.xyz"
atom_full, coord_full = oc.io.extract_coord(file)
my_plot = oc.draw.DrawComplex_Matplotlib(atom=atom_full, coord=coord_full)
my_plot.add_atom()
my_plot.add_bond()
my_plot.add_legend()
my_plot.save_img()
my_plot.show_plot()
# Figure will be saved as Complex_saved_by_OctaDist.png by default.
Other example scripts and octahedral complexes are available at example-py and example-input, respectively.
OctaDist is written entirely in Python 3 binding to Tkinter GUI toolkit. It is cross-platform program which can work on multiple operating systems. The stable version and development build of OctaDist are released at here. A standalone executable for graphical user interface (GUI) and source code for command line interface (CLI) are available for as follows:
Platform | Description |
---|---|
Windows | |
Linux | |
macOS | |
PyPI library | |
Anaconda cloud | |
Nightly build | Development build |
Branch:
git clone https://github.com/OctaDist/OctaDist.git
git checkout nightly-build
git pull origin nightly-build
To get notified when we release a new version of OctaDist, please register at https://cutt.ly/regis-octadist.
The users can post questions in our Google Groups: OctaDist Forum
Please cite this project when you use OctaDist for scientific publication.
Ketkaew, R.; Tantirungrotechai, Y.; Harding, P.; Chastanet, G.; Guionneau, P.; Marchivie, M.; Harding, D. J.
OctaDist: A Tool for Calculating Distortion Parameters in Spin Crossover and Coordination Complexes.
Dalton Trans., 2021,50, 1086-1096. https://doi.org/10.1039/D0DT03988H
BibTeX
@article{Ketkaew2021,
doi = {10.1039/d0dt03988h},
url = {https://doi.org/10.1039/d0dt03988h},
year = {2021},
publisher = {Royal Society of Chemistry ({RSC})},
volume = {50},
number = {3},
pages = {1086--1096},
author = {Rangsiman Ketkaew and Yuthana Tantirungrotechai and Phimphaka Harding and Guillaume Chastanet and Philippe Guionneau and Mathieu Marchivie and David J. Harding},
title = {OctaDist: a tool for calculating distortion parameters in spin crossover and coordination complexes},
journal = {Dalton Transactions}
}
If you found issues in OctaDist, please report it to us at here.
- Rangsiman Ketkaew (University of Zurich, Switzerland)
- E-mail: [email protected]
- Yuthana Tantirungrotechai (Thammasat University, Thailand)
- E-mail: [email protected]
- Phimphaka Harding (Suranaree University of Technology, Thailand)
- E-mail: [email protected]
- Guillaume Chastanet (University of Bordeaux, France)
- E-mail: [email protected]
- Philippe Guionneau (University of Bordeaux, France)
- E-mail: [email protected]
- Mathieu Marchivie (University of Bordeaux, France)
- E-mail: [email protected]
- David J. Harding (Suranaree University of Technology, Thailand)
- E-mail: [email protected]