[TOC]
| category | percent | downloads |
|---|---|---|
| with_mirrors | 100.00% | 2,801 |
| without_mirrors | 20.67% | 579 |
| Total | 2,801 |
Date range: 2023-04-20 - 2023-10-17
This repository is now maintained by Qi Zhang. Thanks to the contribution from Chenxing Luo.
The associated paper is published on Computer Physics Communications.
Please cite this article as: T. Qin, Q. Zhang, R.M. Wentzcovitch et al., qha: A Python package for quasiharmonic free energy calculation for multi-configuration systems, Computer Physics Communications (2018), https://doi.org/10.1016/j.cpc.2018.11.003.
qha is written in Python, and can be installed from Python package index (PyPI) or local source files.
Python 3 can be downloaded from its official website for systems including Windows, macOS, and Linux, please check more details on Python 3 documentation.
To install qha, currently, Python 3.6.x distributions are recommended.
Binary installers for the latest released version are available at the PyPI.
# use PyPI
$ pip install qhaThe source code is currently hosted on GitHub. Please go to the “releases” page to download the tagged releases. Unzip the downloaded sources, go to the top-level directory (e.g., /path/to/repo/qha), run
$ pip install .Notice that you have to use Python version > 3.6.x to install. If you want to install qha in development mode, instead run
$ pip install -e .To run the examples, go to examples/ice VII/ or examples/silicon/ directories and type in terminal:
$ qha run /path/to/settings.yamlIf you want to plot your results, in the same folder, run
$ qha plot /path/to/settings.yamlThe qha source code consists of three major parts.
-
./qhadirectory contains all the source code. -
./examplesdirectory contains two examples,./examples/siliconis the example for single-configuration calculation,./examples/ice VIIis the example for multi-configuration calculation.
The brief of the organization of these directories follows as below:
This main folder contains three folders, license file, readme file, and setup file.
LICENSE.txt: The license file attached with the qha code;
README.md: Readme file of the code, it would be better to view it in a Markdown editor, e.g., Typora;
setup.py: setup file needed for installation of the qha Python package.
qha/__init__.py: Tells Python interpreter that this is a Python package;
qha/calculator.py: Perform single-, multi-configuration calculations, one of the most crucial modules in this code;
qha/fitting.py: Perform the Birch—Murnaghan (BM) equation-of-state (EOS) fitting;
qha/grid_interpolation.py: Find the most suitable volume grid to perform the BM EOS fitting;
qha/plotting.py: A simple module to plot the calculated physical properties;
qha/settings.py: Define some computational settings for the calculation;
qha/single_configuration.py: Calculate the Helmholtz free energy for a single-configuration system;
qha/statmech.py: Define some useful statistical mechanics functions;
qha/thermodynamics.py: Derive the internal energy(
qha/tools.py: Define some miscellaneous functions used in the code, e.g., function used to perform Lagrange interpolation;
qha/type_aliases.py: Define some types for annotation in the code;
qha/unit_conversion.py: A module to convert units used in the calculation;
qha/v2p.py: Contain the function v2p used to convert calculated properties on
qha/input_maker.py: Generate the input file for qha from results obtained from ab initio calculation;
qha/out.py: Functions used to write calculated properties into files.
qha/readers/__init__.py
qha/readers/read_input.py: This module is used to read the input file.
This folder contains files used for the command-line interface.
qha/cli/__init__.py
qha/cli/converter.py
qha/cli/handler.py
qha/cli/parser.py
qha/cli/plotter.py
qha/cli/runner.py
This folder contains files to calculate Helmholtz free energy for the multi-configuration system.
qha/multi_configurations/__init__.py
qha/multi_configurations/different_phonon_dos.py: Work with qha/calculator.py to calculate Helmholtz free energy for the multi-configuration system with different phonon density of states (VDOS) for each configuration;
qha/multi_configurations/same_phonon_dos.py: Work with qha/calculator.py to calculate Helmholtz free energy for multi-configuration system with the same VDOS for all configurations.
this folder contains unit test files
qha/tests/__init__.py
qha/tests/test_overall_run.py
qha/tests/test_read_input.py
qha/tests/test_samevdos_overall.py
qha/tests/test_single_configuration.py
qha/tests/test_unit_conversion.py
This folder contains two examples for demonstration purpose.
This folder conations an example to perform the single-configuration calculation. Also, an example to generate the input file for the qha code is included, check examples/silicon/make_input/README for details;
examples/silicon/input: The input file for qha;
examples/silicon/settings.yaml: This file is the computational settings file.
examples/ice VII/input_01 : input_01 through input_52 are the input files of 52 distinguish configurations;
examples/ice VII/input_02
examples/ice VII/input_03
…
examples/ice VII/input_52
examples/ice VII/settings.yaml: This file is the computational settings file, see our online tutorial for more details.
The official documentation is hosted on our GitHub page.
