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478 lines
21 KiB
ReStructuredText
.. _conversion:
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Orbital construction and conversion
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===================================
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The first step for a DMFT calculation is to provide the necessary
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input based on a DFT calculation. We will not review how to do the DFT
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calculation here in this documentation, but refer the user to the
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documentation and tutorials that come with the actual DFT
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package. Here, we will describe how to use output created by Wien2k,
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as well as how to use the light-weight general interface.
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Interface with Wien2k
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---------------------
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We assume that the user has obtained a self-consistent solution of the
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Kohn-Sham equations. We further have to require that the user is
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familiar with the main in/output files of Wien2k, and how to run
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the DFT code.
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Conversion for the DMFT self-consistency cycle
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""""""""""""""""""""""""""""""""""""""""""""""
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First, we have to write the necessary
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quantities into a file that can be processed further by invoking in a
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shell the command
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`x lapw2 -almd`
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We note that any other flag for lapw2, such as -c or -so (for
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spin-orbit coupling) has to be added also to this line. This creates
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some files that we need for the Wannier orbital construction.
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The orbital construction itself is done by the Fortran program
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:program:`dmftproj`. For an extensive manual to this program see
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:download:`TutorialDmftproj.pdf <images_scripts/TutorialDmftproj.pdf>`.
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Here we will only describe the basic steps.
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Let us take the compound SrVO3, a commonly used
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example for DFT+DMFT calculations. The input file for
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:program:`dmftproj` looks like
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.. literalinclude:: images_scripts/SrVO3.indmftpr
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The first three lines give the number of inequivalent sites, their
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multiplicity (to be in accordance with the Wien2k *struct* file) and
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the maximum orbital quantum number :math:`l_{max}`. In our case our
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struct file contains the atoms in the order Sr, V, O.
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Next we have to
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specify for each of the inequivalent sites, whether we want to treat
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their orbitals as correlated or not. This information is given by the
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following 3 to 5 lines:
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#. We specify which basis set is used (complex or cubic
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harmonics).
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#. The four numbers refer to *s*, *p*, *d*, and *f* electrons,
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resp. Putting 0 means doing nothing, putting 1 will calculate
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**unnormalized** projectors in compliance with the Wien2k
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definition. The important flag is 2, this means to include these
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electrons as correlated electrons, and calculate normalized Wannier
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functions for them. In the example above, you see that only for the
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vanadium *d* we set the flag to 2. If you want to do simply a DMFT
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calculation, then set everything to 0, except one flag 2 for the
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correlated electrons.
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#. In case you have a irrep splitting of the correlated shell, you can
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specify here how many irreps you have. You see that we put 2, since
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eg and t2g symmetries are irreps in this cubic case. If you don't
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want to use this splitting, just put 0.
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#. (optional) If you specifies a number different from 0 in above line, you have
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to tell now, which of the irreps you want to be treated
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correlated. We want to t2g, and not the eg, so we set 0 for eg and
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1 for t2g. Note that the example above is what you need in 99% of
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the cases when you want to treat only t2g electrons. For eg's only
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(e.g. nickelates), you set 10 and 01 in this line.
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#. (optional) If you have specified a correlated shell for this atom,
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you have to tell if spin-orbit coupling should be taken into
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account. 0 means no, 1 is yes.
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These lines have to be repeated for each inequivalent atom.
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The last line gives the energy window, relative to the Fermi energy,
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that is used for the projective Wannier functions. Note that, in
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accordance with Wien2k, we give energies in Rydberg units!
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After setting up this input file, you run:
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`dmftproj`
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Again, adding possible flags like -so for spin-orbit coupling. This
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program produces the following files (in the following, take *case* as
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the standard Wien2k place holder, to be replaced by the actual working
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directory name):
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* :file:`case.ctqmcout` and :file:`case.symqmc` containing projector
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operators and symmetry operations for orthonormalized Wannier
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orbitals, respectively.
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* :file:`case.parproj` and :file:`case.sympar` containing projector
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operators and symmetry operations for uncorrelated states,
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respectively. These files are needed for projected
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density-of-states or spectral-function calculations in
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post-processing only.
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* :file:`case.oubwin` needed for the charge density recalculation in
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the case of fully self-consistent DFT+DMFT run (see below).
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Now we convert these files into an hdf5 file that can be used for the
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DMFT calculations. For this purpose we
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use the python module :class:`Wien2kConverter <dft.converters.wien2k_converter.Wien2kConverter>`. It is initialized as::
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from pytriqs.applications.dft.converters.wien2k_converter import *
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Converter = Wien2kConverter(filename = case)
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The only necessary parameter to this construction is the parameter `filename`.
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It has to be the root of the files produces by dmftproj. For our
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example, the :program:`Wien2k` naming convention is that all files are
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called the same, for instance
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:file:`SrVO3.*`, so you would give `filename = "SrVO3"`. The constructor opens
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an hdf5 archive, named :file:`case.h5`, where all the data is
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stored. For other parameters of the constructor please visit the
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:ref:`refconverters` section of the reference manual.
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After initializing the interface module, we can now convert the input
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text files to the hdf5 archive by::
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Converter.convert_dft_input()
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This reads all the data, and stores it in the file :file:`case.h5`.
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In this step, the files :file:`case.ctqmcout` and
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:file:`case.symqmc`
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have to be present in the working directory.
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After this step, all the necessary information for the DMFT loop is
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stored in the hdf5 archive, where the string variable
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`Converter.hdf_filename` gives the file name of the archive.
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At this point you should use the method :meth:`dos_wannier_basis <dft.sumk_dft_tools.SumkDFTTools.dos_wannier_basis>`
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contained in the module :class:`SumkDFTTools <dft.sumk_dft_tools.SumkDFTTools>` to check the density of
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states of the Wannier orbitals (see :ref:`analysis`).
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You have now everything for performing a DMFT calculation, and you can
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proceed with the section on :ref:`single-shot DFT+DMFT calculations <singleshot>`.
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Data for post-processing
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""""""""""""""""""""""""
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In case you want to do post-processing of your data using the module
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:class:`SumkDFTTools <dft.sumk_dft_tools.SumkDFTTools>`, some more files
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have to be converted to the hdf5 archive. For instance, for
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calculating the partial density of states or partial charges
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consistent with the definition of :program:`Wien2k`, you have to invoke::
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Converter.convert_parproj_input()
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This reads and converts the files :file:`case.parproj` and
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:file:`case.sympar`.
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If you want to plot band structures, one has to do the
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following. First, one has to do the Wien2k calculation on the given
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:math:`\mathbf{k}`-path, and run :program:`dmftproj` on that path:
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| `x lapw1 -band`
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| `x lapw2 -band -almd`
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| `dmftproj -band`
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Again, maybe with the optional additional extra flags according to
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Wien2k. Now we use a routine of the converter module allows to read
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and convert the input for :class:`SumkDFTTools <dft.sumk_dft_tools.SumkDFTTools>`::
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Converter.convert_bands_input()
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After having converted this input, you can further proceed with the
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:ref:`analysis`. For more options on the converter module, please have
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a look at the :ref:`refconverters` section of the reference manual.
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Data for transport calculations
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"""""""""""""""""""""""""""""""
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For the transport calculations, the situation is a bit more involved,
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since we need also the :program:`optics` package of Wien2k. Please
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look at the section on :ref:`Transport` to see how to do the necessary
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steps, including the conversion.
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Interface with VASP
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---------------------
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.. warning::
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The VASP interface is in the alpha-version and the VASP part of it is not
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yet publicly released. The documentation may, thus, be subject to changes
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before the final release.
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The interface with VASP relies on new options introduced since
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version 5.4.x. The output of raw (non-normalized) projectors is
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controlled by an INCAR option LOCPROJ whose complete syntax is described in
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VASP documentaion.
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The definition of a projector set starts with specifying which sites
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and which local states we are going to project onto.
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This information is provided by option LOCPROJ
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| `LOCPROJ = <sites> : <shells> : <projector type>`
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where `<sites>` represents a list of site indices separated by spaces,
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with the indices corresponding to the site position in the POSCAR file;
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`<shells>` specifies local states (e.g. :math:`s`, :math:`p`, :math:`d`,
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:math:`d_{x^2-y^2}`, etc.);
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`<projector type>` chooses a particular type of the local basis function.
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Some projector types also require parameters `EMIN`, `EMAX` in INCAR to
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be set to define an (approximate) energy window corresponding to the
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valence states.
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When either a self-consistent (`ICHARG < 10`) or a non-self-consistent
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(`ICHARG >= 10`) calculation is done VASP produces file `LOCPROJ` which
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will serve as the main input for the conversion routine.
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Conversion for the DMFT self-consistency cycle
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""""""""""""""""""""""""""""""""""""""""""""""
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In order to use the projectors generated by VASP for defining an
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impurity problem they must be processed, i.e. normalized, possibly
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transformed, and then converted to a format suitable for DFT_tools scripts.
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The processing of projectors is performed by the program :program:`plovasp`
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invoked as
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| `plovasp <plo.cfg>`
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where `<plo.cfg>` is a input file controlling the conversion of projectors.
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The format of input file `<plo.cfg>` is described in details in
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:ref:`plovasp`. Here we just give a simple example for the case
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of SrVO3:
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.. literalinclude:: images_scripts/srvo3.cfg
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A projector shell is defined by a section `[Shell 1]` where the number
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can be arbitrary and used only for user convenience. Several
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parameters are required
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- **IONS**: list of site indices which must be a subset of indices
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given earlier in `LOCPROJ`.
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- **LSHELL**: :math:`l`-quantum number of the projector shell; the corresponding
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orbitals must be present in `LOCPROJ`.
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- **EWINDOW**: energy window in which the projectors are normalized;
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note that the energies are defined with respect to the Fermi level.
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Option **TRANSFORM** is optional but here it is specified to extract
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only three :math:`t_{2g}` orbitals out of five `d` orbitals given by
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:math:`l = 2`.
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A general H(k)
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--------------
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In addition to the more complicated Wien2k converter,
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:program:`DFTTools` contains also a light converter. It takes only
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one inputfile, and creates the necessary hdf outputfile for
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the DMFT calculation. The header of this input file has a defined
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format, an example is the following:
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.. literalinclude:: images_scripts/case.hk
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The lines of this header define
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#. Number of :math:`\mathbf{k}`-points used in the calculation
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#. Electron density for setting the chemical potential
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#. Number of total atomic shells in the hamiltonian matrix. In short,
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this gives the number of lines described in the following. IN the
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example file give above this number is 2.
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#. The next line(s) contain four numbers each: index of the atom, index
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of the equivalent shell, :math:`l` quantum number, dimension
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of this shell. Repeat this line for each atomic shell, the number
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of the shells is given in the previous line.
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In the example input file given above, we have two inequivalent
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atomic shells, one on atom number 1 with a full d-shell (dimension 5),
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and one on atom number 2 with one p-shell (dimension 3).
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Other examples for these lines are:
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#. Full d-shell in a material with only one correlated atom in the
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unit cell (e.g. SrVO3). One line is sufficient and the numbers
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are `1 1 2 5`.
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#. Full d-shell in a material with two equivalent atoms in the unit
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cell (e.g. FeSe): You need two lines, one for each equivalent
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atom. First line is `1 1 2 5`, and the second line is
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`2 1 2 5`. The only difference is the first number, which tells on
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which atom the shell is located. The second number is the
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same in both lines, meaning that both atoms are equivalent.
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#. t2g orbitals on two non-equivalent atoms in the unit cell: Two
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lines again. First line is `1 1 2 3`, second line `2 2 2 3`. The
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difference to the case above is that now also the second number
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differs. Therefore, the two shells are treated independently in
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the calculation.
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#. d-p Hamiltonian in a system with two equivalent atoms each in
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the unit cell (e.g. FeSe has two Fe and two Se in the unit
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cell). You need for lines. First line `1 1 2 5`, second
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line
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`2 1 2 5`. These two lines specify Fe as in the case above. For the p
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orbitals you need line three as `3 2 1 3` and line four
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as `4 2 1 3`. We have 4 atoms, since the first number runs from 1 to 4,
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but only two inequivalent atoms, since the second number runs
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only form 1 to 2.
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Note that the total dimension of the hamiltonian matrices that are
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read in is the sum of all shell dimensions that you specified. For
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example number 4 given above we have a dimension of 5+5+3+3=16. It is important
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that the order of the shells that you give here must be the same as
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the order of the orbitals in the hamiltonian matrix. In the last
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example case above the code assumes that matrix index 1 to 5
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belongs to the first d shell, 6 to 10 to the second, 11 to 13 to
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the first p shell, and 14 to 16 the second p shell.
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#. Number of correlated shells in the hamiltonian matrix, in the same
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spirit as line 3.
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#. The next line(s) contain six numbers: index of the atom, index
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of the equivalent shell, :math:`l` quantum number, dimension
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of the correlated shells, a spin-orbit parameter, and another
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parameter defining interactions. Note that the latter two
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parameters are not used at the moment in the code, and only kept
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for compatibility reasons. In our example file we use only the
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d-shell as correlated, that is why we have only one line here.
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#. The last line contains several numbers: the number of irreducible
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representations, and then the dimensions of the irreps. One
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possibility is as the example above, another one would be 2
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2 3. This would mean, 2 irreps (eg and t2g), of dimension 2 and 3,
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resp.
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After these header lines, the file has to contain the Hamiltonian
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matrix in orbital space. The standard convention is that you give for
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each :math:`\mathbf{k}`-point first the matrix of the real part, then the
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matrix of the imaginary part, and then move on to the next :math:`\mathbf{k}`-point.
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The converter itself is used as::
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from pytriqs.applications.dft.converters.hk_converter import *
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Converter = HkConverter(filename = hkinputfile)
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Converter.convert_dft_input()
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where :file:`hkinputfile` is the name of the input file described
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above. This produces the hdf file that you need for a DMFT calculation.
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For more options of this converter, have a look at the
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:ref:`refconverters` section of the reference manual.
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Wannier90 Converter
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-------------------
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Using this converter it is possible to convert the output of
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`wannier90 <http://wannier.org>`_
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Maximally Localized Wannier Functions (MLWF) and create a HDF5 archive
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suitable for one-shot DMFT calculations with the
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:class:`SumkDFT <dft.sumk_dft.SumkDFT>` class.
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The user must supply two files in order to run the Wannier90 Converter:
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#. The file :file:`seedname_hr.dat`, which contains the DFT Hamiltonian
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in the MLWF basis calculated through :program:`wannier90` with ``hr_plot = true``
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(please refer to the :program:`wannier90` documentation).
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#. A file named :file:`seedname.inp`, which contains the required
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information about the :math:`\mathbf{k}`-point mesh, the electron density,
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the correlated shell structure, ... (see below).
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Here and in the following, the keyword ``seedname`` should always be intended
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as a placeholder for the actual prefix chosen by the user when creating the
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input for :program:`wannier90`.
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Once these two files are available, one can use the converter as follows::
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from pytriqs.applications.dft.converters import Wannier90Converter
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Converter = Wannier90Converter(seedname='seedname')
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Converter.convert_dft_input()
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The converter input :file:`seedname.inp` is a simple text file with
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the following format:
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.. literalinclude:: images_scripts/LaVO3_w90.inp
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The example shows the input for the perovskite crystal of LaVO\ :sub:`3`
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in the room-temperature `Pnma` symmetry. The unit cell contains four
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symmetry-equivalent correlated sites (the V atoms) and the total number
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of electrons per unit cell is 8 (see second line).
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The first line specifies how to generate the :math:`\mathbf{k}`-point
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mesh that will be used to obtain :math:`H(\mathbf{k})`
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by Fourier transforming :math:`H(\mathbf{R})`.
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Currently implemented options are:
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* :math:`\Gamma`-centered uniform grid with dimensions
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:math:`n_{k_x} \times n_{k_y} \times n_{k_z}`;
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specify ``0`` followed by the three grid dimensions,
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like in the example above
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* :math:`\Gamma`-centered uniform grid with dimensions
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automatically determined by the converter (from the number of
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:math:`\mathbf{R}` vectors found in :file:`seedname_hr.dat`);
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just specify ``-1``
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Inside :file:`seedname.inp`, it is crucial to correctly specify the
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correlated shell structure, which depends on the contents of the
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:program:`wannier90` output :file:`seedname_hr.dat` and on the order
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of the MLWFs contained in it.
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The number of MLWFs must be equal to, or greater than the total number
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of correlated orbitals (i.e., the sum of all ``dim`` in :file:`seedname.inp`).
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If the converter finds fewer MLWFs inside :file:`seedname_hr.dat`, then it
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stops with an error; if it finds more MLWFs, then it assumes that the
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additional MLWFs correspond to uncorrelated orbitals (e.g., the O-\ `2p` shells).
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When reading the hoppings :math:`\langle w_i | H(\mathbf{R}) | w_j \rangle`
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(where :math:`w_i` is the :math:`i`-th MLWF), the converter also assumes that
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the first indices correspond to the correlated shells (in our example,
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the V-t\ :sub:`2g` shells). Therefore, the MLWFs corresponding to the
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uncorrelated shells (if present) must be listed **after** those of the
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correlated shells.
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With the :program:`wannier90` code, this can be achieved this by listing the
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projections for the uncorrelated shells after those for the correlated shells.
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In our `Pnma`-LaVO\ :sub:`3` example, for instance, we could use::
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Begin Projections
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V:l=2,mr=2,3,5:z=0,0,1:x=-1,1,0
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O:l=1:mr=1,2,3:z=0,0,1:x=-1,1,0
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End Projections
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where the ``x=-1,1,0`` option indicates that the V--O bonds in the octahedra are
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rotated by (approximatively) 45 degrees with respect to the axes of the `Pbnm` cell.
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The converter will analyze the matrix elements of the local Hamiltonian
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to find the symmetry matrices `rot_mat` needed for the global-to-local
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transformation of the basis set for correlated orbitals
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(see section :ref:`hdfstructure`).
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The matrices are obtained by finding the unitary transformations that diagonalize
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:math:`\langle w_i | H_I(\mathbf{R}=0,0,0) | w_j \rangle`, where :math:`I` runs
|
|
over the correlated shells and `i,j` belong to the same shell (more details elsewhere...).
|
|
If two correlated shells are defined as equivalent in :file:`seedname.inp`,
|
|
then the corresponding eigenvalues have to match within a threshold of 10\ :sup:`-5`,
|
|
otherwise the converter will produce an error/warning.
|
|
If this happens, please carefully check your data in :file:`seedname_hr.dat`.
|
|
This method might fail in non-trivial cases (i.e., more than one correlated
|
|
shell is present) when there are some degenerate eigenvalues:
|
|
so far tests have not shown any issue, but one must be careful in those cases
|
|
(the converter will print a warning message).
|
|
|
|
The current implementation of the Wannier90 Converter has some limitations:
|
|
|
|
* Since :program:`wannier90` does not make use of symmetries (symmetry-reduction
|
|
of the :math:`\mathbf{k}`-point grid is not possible), the converter always
|
|
sets ``symm_op=0`` (see the :ref:`hdfstructure` section).
|
|
* No charge self-consistency possible at the moment.
|
|
* Calculations with spin-orbit (``SO=1``) are not supported.
|
|
* The spin-polarized case (``SP=1``) is not yet tested.
|
|
* The post-processing routines in the module
|
|
:class:`SumkDFTTools <dft.sumk_dft_tools.SumkDFTTools>`
|
|
were not tested with this converter.
|
|
* ``proj_mat_all`` are not used, so there are no projectors onto the
|
|
uncorrelated orbitals for now.
|
|
|
|
|
|
MPI issues
|
|
----------
|
|
|
|
The interface packages are written such that all the file operations
|
|
are done only on the master node. In general, the philosophy of the
|
|
package is that whenever you read in something from the archive
|
|
yourself, you have to *manually* broadcast it to the nodes. An
|
|
exception to this rule is when you use routines from :class:`SumkDFT <dft.sumk_dft.SumkDFT>`
|
|
or :class:`SumkDFTTools <dft.sumk_dft_tools.SumkDFTTools>`, where the broadcasting is done for you.
|
|
|
|
Interfaces to other packages
|
|
----------------------------
|
|
|
|
Because of the modular structure, it is straight forward to extend the :ref:`TRIQS <triqslibs:welcome>` package
|
|
in order to work with other band-structure codes. The only necessary requirement is that
|
|
the interface module produces an hdf5 archive, that stores all the data in the specified
|
|
form. For the details of what data is stored in detail, see the
|
|
:ref:`hdfstructure` part of the reference manual.
|