Metadata-Version: 2.1
Name: effmass
Version: 1.1.0
Summary: An effective mass package
Home-page: https://github.com/lucydot/effmass
Author: Lucy Whalley
Author-email: lucywhalley@gmail.com
License: MIT
Download-URL: https://github.com/lucydot/effmass/archive/1.1.0.tar.gz
Description: # effmass
        
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        `effmass` is a Python 3 package for calculating various definitions of effective mass from the electronic bandstructure of a semiconducting material. It consists of a core class that calculates the effective mass and other associated properties of selected bandstructure segments. The module also contains functions for locating bandstructure extrema and plotting approximations to the dispersion.
        
        Examples are provided in a Jupyter notebook [here](https://nbviewer.jupyter.org/github/lucydot/effmass/blob/master/paper/notebook.ipynb).
        API documentation is [here](https://effmass.readthedocs.io/en/latest/).
        Source code is available as a git repository at [https://github.com/lucydot/effmass](https://github.com/lucydot/effmass).
        
        The [paper](https://github.com/lucydot/effmass/paper) directory contains the Vasp input data (POSCAR), Vasp output data (OUTCAR/PROCAR) and band structures generated for an academic paper using this software: *Impact of nonparabolic electronic band structure on the optical and transport properties of photovoltaic materials*  
        Phys. Rev. B **99** (8), 085207 - also avaiable on [arXiv](https://arxiv.org/pdf/1811.02281.pdf)..
        
        ## Features
        
        `effmass` can:
        
        **Read in a bandstructure:**
        This requires the `VASP` output files `PROCAR` and `OUTCAR`. It is assumed you have walked through a 1D slice of the Brillouin Zone, capturing the maxima and minima of interest. `effmass` uses the Python package [vasppy](https://github.com/bjmorgan/vasppy) for parsing `VASP` output.
        
        **Locate extrema:**
        These correspond to the valence band maxima and conduction band minima. Maxima and minima within a certain energy range can also be located.
        
        **Calculate curvature, transport and optical effective masses:**
        The curvature (aka inertial) and transport masses are calculated using the derivatives of a fitted polynomial function. The optical effective mass can also be calculated assuming a Kane dispersion.
        
        **Assess the extent of non-parabolicity:**
        Parameters of the Kane quasi-linear dispersion are calculated to quantify the extent of non-parabolicity over a given energy range. 
        
        **Calculate the quasi-fermi level for a given carrier concentration:**
        This requires the `VASP` output file `DOSCAR`. Using density-of-states data and assuming no thermal smearing, `effmass` can calculate the energy to which states are occupied. This is a useful approximation to the quasi-Fermi level.
        
        **Plot fits to the dispersion:**
        Selected bandstructure segments and approximations to the dispersion (assuming a Kane, quadratic, or higher order fit) can be visualised.
        
        The `effmass` package is aimed towards theoretical solid state physicists and chemists who have a basic familiarity with Python. Depending on the functionality and level of approximation you are looking for, 
        it may be that one of the packages listed [here](https://effmass.readthedocs.io/en/latest/Related%20packages.html) will suit your needs better.
        
        ## Development
        
        Please use the Github [issue tracker](https://github.com/lucydot/effmass/issues/) for feature requests and bug reports. 
        
        If you would like to contribute please do so via a pull request. All contributors must read and respect the [code of conduct](https://github.com/lucydot/effmass/blob/master/CODE_OF_CONDUCT.md). In particular, we welcome contributions which would extend `effmass` so that it is able to parse output from other electronic structure codes. 
        
        ## Installation
        
        `effmass` is a Python 3 package and requires key packages from the [SciPy ecosystem](https://www.scipy.org/about.html): SciPy, NumPy and Matplotlib. If you have not installed these packages before, it may be best to install them using your preferred package manager (eg: Homebrew). Note that together they will use >100MB of disk space. `effmass` can then be built using the Python package manager `pip`:
        
        ```
        pip3 install --user effmass
        ```
        
        Or download the latest release from [GitHub](https://github.com/lucydot/effmass/releases), and install
        ```
        cd effmass
        python3 setup.py install
        ```
        
        Or clone the latest development version
        ```
        git clone git@github.com:lucydot/effmass.git
        ```
        and install the same way.
        ```
        cd effmass
        python3 setup.py install 
        ```
        
        ## Tests
        
        Automated testing of the latest commit happens [here](https://travis-ci.com/lucydot/effmass).
        
        Manual tests can be run using 
        ```
        python3 -m pytest
        ```
        
        This code has been tested with Python versions 3.6.
        
        ## Documentation
        
        An overview of the features of effmass along with example code is contained in a [Jupyter notebook](https://nbviewer.jupyter.org/github/lucydot/effmass/blob/master/paper/notebook.ipynb), which is available in the `paper` directory.
        
        API documentation is available [here](https://effmass.readthedocs.io/en/latest/).
        
        ## Citing `effmass`
        
        If you use this code in your research, please cite the following paper:
        
        Whalley, Lucy D. (2018). *effmass - an effective mass package*. The Journal of Open Source Software, 3(28) 797.
        
        ### Bibtex
        
        ```
        @misc{Whalley_JOSS2018,
          author       = {Lucy D. Whalley},
          title        = {effmass: An effective mass package},
          volume       = {3},
          issue        = {28},
          pages        = {797},
          month        = {Aug},
          year         = {2018},
          doi          = {10.21105/joss.00797},
          url          = {http://joss.theoj.org/papers/10.21105/joss.00797}
        }
        ```
        
Platform: UNKNOWN
Requires-Python: >=3.6
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