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##########################################################################
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#
# TRIQS: a Toolbox for Research in Interacting Quantum Systems
#
# Copyright (C) 2011 by M. Aichhorn, L. Pourovskii, V. Vildosola
#
# TRIQS is free software: you can redistribute it and/or modify it under the
# terms of the GNU General Public License as published by the Free Software
# Foundation, either version 3 of the License, or (at your option) any later
# version.
#
# TRIQS is distributed in the hope that it will be useful, but WITHOUT ANY
# WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS
# FOR A PARTICULAR PURPOSE. See the GNU General Public License for more
# details.
#
# You should have received a copy of the GNU General Public License along with
# TRIQS. If not, see <http://www.gnu.org/licenses/>.
#
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##########################################################################
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import sys
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from types import *
import numpy
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from pytriqs . gf import *
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import pytriqs . utility . mpi as mpi
from symmetry import *
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from sumk_dft import SumkDFT
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from scipy . integrate import *
from scipy . interpolate import *
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if not hasattr ( numpy , ' full ' ) :
# polyfill full for older numpy:
numpy . full = lambda a , f : numpy . zeros ( a ) + f
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class SumkDFTTools ( SumkDFT ) :
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"""
Extends the SumkDFT class with some tools for analysing the data .
"""
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def __init__ ( self , hdf_file , h_field = 0.0 , use_dft_blocks = False , dft_data = ' dft_input ' , symmcorr_data = ' dft_symmcorr_input ' ,
parproj_data = ' dft_parproj_input ' , symmpar_data = ' dft_symmpar_input ' , bands_data = ' dft_bands_input ' ,
transp_data = ' dft_transp_input ' , misc_data = ' dft_misc_input ' ) :
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"""
Initialisation of the class . Parameters are exactly as for SumKDFT .
"""
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SumkDFT . __init__ ( self , hdf_file = hdf_file , h_field = h_field , use_dft_blocks = use_dft_blocks ,
dft_data = dft_data , symmcorr_data = symmcorr_data , parproj_data = parproj_data ,
symmpar_data = symmpar_data , bands_data = bands_data , transp_data = transp_data ,
misc_data = misc_data )
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# Uses .data of only GfReFreq objects.
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def dos_wannier_basis ( self , mu = None , broadening = None , mesh = None , with_Sigma = True , with_dc = True , save_to_file = True ) :
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"""
Calculates the density of states in the basis of the Wannier functions .
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Parameters
- - - - - - - - - -
mu : double , optional
Chemical potential , overrides the one stored in the hdf5 archive .
broadening : double , optional
Lorentzian broadening of the spectra . If not given , standard value of lattice_gf is used .
mesh : real frequency MeshType , optional
Omega mesh for the real - frequency Green ' s function. Given as parameter to lattice_gf.
with_Sigma : boolean , optional
If True , the self energy is used for the calculation . If false , the DOS is calculated without self energy .
with_dc : boolean , optional
If True the double counting correction is used .
save_to_file : boolean , optional
If True , text files with the calculated data will be created .
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Returns
- - - - - - -
DOS : Dict of numpy arrays
Contains the full density of states .
DOSproj : Dict of numpy arrays
DOS projected to atoms .
DOSproj_orb : Dict of numpy arrays
DOS projected to atoms and resolved into orbital contributions .
"""
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if ( mesh is None ) and ( not with_Sigma ) :
raise ValueError , " lattice_gf: Give the mesh=(om_min,om_max,n_points) for the lattice GfReFreq. "
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if mesh is None :
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om_mesh = [ x . real for x in self . Sigma_imp_w [ 0 ] . mesh ]
om_min = om_mesh [ 0 ]
om_max = om_mesh [ - 1 ]
n_om = len ( om_mesh )
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mesh = ( om_min , om_max , n_om )
else :
om_min , om_max , n_om = mesh
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om_mesh = numpy . linspace ( om_min , om_max , n_om )
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G_loc = [ ]
for icrsh in range ( self . n_corr_shells ) :
spn = self . spin_block_names [ self . corr_shells [ icrsh ] [ ' SO ' ] ]
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glist = [ GfReFreq ( indices = inner , window = ( om_min , om_max ) , n_points = n_om )
for block , inner in self . gf_struct_sumk [ icrsh ] ]
G_loc . append (
BlockGf ( name_list = spn , block_list = glist , make_copies = False ) )
for icrsh in range ( self . n_corr_shells ) :
G_loc [ icrsh ] . zero ( )
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DOS = { sp : numpy . zeros ( [ n_om ] , numpy . float_ )
for sp in self . spin_block_names [ self . SO ] }
DOSproj = [ { } for ish in range ( self . n_inequiv_shells ) ]
DOSproj_orb = [ { } for ish in range ( self . n_inequiv_shells ) ]
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for ish in range ( self . n_inequiv_shells ) :
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for sp in self . spin_block_names [ self . corr_shells [ self . inequiv_to_corr [ ish ] ] [ ' SO ' ] ] :
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dim = self . corr_shells [ self . inequiv_to_corr [ ish ] ] [ ' dim ' ]
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DOSproj [ ish ] [ sp ] = numpy . zeros ( [ n_om ] , numpy . float_ )
DOSproj_orb [ ish ] [ sp ] = numpy . zeros (
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[ n_om , dim , dim ] , numpy . complex_ )
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ikarray = numpy . array ( range ( self . n_k ) )
for ik in mpi . slice_array ( ikarray ) :
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G_latt_w = self . lattice_gf (
ik = ik , mu = mu , iw_or_w = " w " , broadening = broadening , mesh = mesh , with_Sigma = with_Sigma , with_dc = with_dc )
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G_latt_w * = self . bz_weights [ ik ]
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# Non-projected DOS
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for iom in range ( n_om ) :
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for bname , gf in G_latt_w :
DOS [ bname ] [ iom ] - = gf . data [ iom , : , : ] . imag . trace ( ) / \
numpy . pi
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# Projected DOS:
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for icrsh in range ( self . n_corr_shells ) :
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tmp = G_loc [ icrsh ] . copy ( )
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for bname , gf in tmp :
tmp [ bname ] << self . downfold ( ik , icrsh , bname , G_latt_w [
bname ] , gf ) # downfolding G
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G_loc [ icrsh ] + = tmp
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# Collect data from mpi:
for bname in DOS :
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DOS [ bname ] = mpi . all_reduce (
mpi . world , DOS [ bname ] , lambda x , y : x + y )
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for icrsh in range ( self . n_corr_shells ) :
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G_loc [ icrsh ] << mpi . all_reduce (
mpi . world , G_loc [ icrsh ] , lambda x , y : x + y )
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mpi . barrier ( )
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# Symmetrize and rotate to local coord. system if needed:
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if self . symm_op != 0 :
G_loc = self . symmcorr . symmetrize ( G_loc )
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if self . use_rotations :
for icrsh in range ( self . n_corr_shells ) :
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for bname , gf in G_loc [ icrsh ] :
G_loc [ icrsh ] [ bname ] << self . rotloc (
icrsh , gf , direction = ' toLocal ' )
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# G_loc can now also be used to look at orbitally-resolved quantities
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for ish in range ( self . n_inequiv_shells ) :
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for bname , gf in G_loc [ self . inequiv_to_corr [ ish ] ] : # loop over spins
for iom in range ( n_om ) :
DOSproj [ ish ] [ bname ] [ iom ] - = gf . data [ iom ,
: , : ] . imag . trace ( ) / numpy . pi
DOSproj_orb [ ish ] [ bname ] [
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: , : , : ] + = ( 1.0 j * ( gf - gf . conjugate ( ) . transpose ( ) ) / 2.0 / numpy . pi ) . data [ : , : , : ]
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# Write to files
if save_to_file and mpi . is_master_node ( ) :
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for sp in self . spin_block_names [ self . SO ] :
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f = open ( ' DOS_wann_ %s .dat ' % sp , ' w ' )
for iom in range ( n_om ) :
f . write ( " %s %s \n " % ( om_mesh [ iom ] , DOS [ sp ] [ iom ] ) )
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f . close ( )
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# Partial
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for ish in range ( self . n_inequiv_shells ) :
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f = open ( ' DOS_wann_ %s _proj %s .dat ' % ( sp , ish ) , ' w ' )
for iom in range ( n_om ) :
f . write ( " %s %s \n " %
( om_mesh [ iom ] , DOSproj [ ish ] [ sp ] [ iom ] ) )
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f . close ( )
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# Orbitally-resolved
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for i in range ( self . corr_shells [ self . inequiv_to_corr [ ish ] ] [ ' dim ' ] ) :
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for j in range ( i , self . corr_shells [ self . inequiv_to_corr [ ish ] ] [ ' dim ' ] ) :
f = open ( ' DOS_wann_ ' + sp + ' _proj ' + str ( ish ) +
' _ ' + str ( i ) + ' _ ' + str ( j ) + ' .dat ' , ' w ' )
for iom in range ( n_om ) :
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f . write ( " %s %s %s \n " % (
om_mesh [ iom ] , DOSproj_orb [ ish ] [ sp ] [ iom , i , j ] . real , DOSproj_orb [ ish ] [ sp ] [ iom , i , j ] . imag ) )
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f . close ( )
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return DOS , DOSproj , DOSproj_orb
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# Uses .data of only GfReFreq objects.
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def dos_parproj_basis ( self , mu = None , broadening = None , mesh = None , with_Sigma = True , with_dc = True , save_to_file = True ) :
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"""
Calculates the orbitally - resolved DOS .
Different to dos_Wannier_basis is that here we calculate projections also to non - Wannier projectors , in the
flavour of Wien2k QTL calculatuions .
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Parameters
- - - - - - - - - -
mu : double , optional
Chemical potential , overrides the one stored in the hdf5 archive .
broadening : double , optional
Lorentzian broadening of the spectra . If not given , standard value of lattice_gf is used .
mesh : real frequency MeshType , optional
Omega mesh for the real - frequency Green ' s function. Given as parameter to lattice_gf.
with_Sigma : boolean , optional
If True , the self energy is used for the calculation . If false , the DOS is calculated without self energy .
with_dc : boolean , optional
If True the double counting correction is used .
save_to_file : boolean , optional
If True , text files with the calculated data will be created .
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Returns
- - - - - - -
DOS : Dict of numpy arrays
Contains the full density of states .
DOSproj : Dict of numpy arrays
DOS projected to atoms .
DOSproj_orb : Dict of numpy arrays
DOS projected to atoms and resolved into orbital contributions .
"""
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things_to_read = [ ' n_parproj ' , ' proj_mat_all ' ,
' rot_mat_all ' , ' rot_mat_all_time_inv ' ]
value_read = self . read_input_from_hdf (
subgrp = self . parproj_data , things_to_read = things_to_read )
if not value_read :
return value_read
if self . symm_op :
self . symmpar = Symmetry ( self . hdf_file , subgroup = self . symmpar_data )
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if ( mesh is None ) and ( not with_Sigma ) :
raise ValueError , " lattice_gf: Give the mesh=(om_min,om_max,n_points) for the lattice GfReFreq. "
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if mesh is None :
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om_mesh = [ x . real for x in self . Sigma_imp_w [ 0 ] . mesh ]
om_min = om_mesh [ 0 ]
om_max = om_mesh [ - 1 ]
n_om = len ( om_mesh )
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mesh = ( om_min , om_max , n_om )
else :
om_min , om_max , n_om = mesh
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om_mesh = numpy . linspace ( om_min , om_max , n_om )
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G_loc = [ ]
spn = self . spin_block_names [ self . SO ]
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gf_struct_parproj = [ [ ( sp , range ( self . shells [ ish ] [ ' dim ' ] ) ) for sp in spn ]
for ish in range ( self . n_shells ) ]
for ish in range ( self . n_shells ) :
glist = [ GfReFreq ( indices = inner , window = ( om_min , om_max ) , n_points = n_om )
for block , inner in gf_struct_parproj [ ish ] ]
G_loc . append (
BlockGf ( name_list = spn , block_list = glist , make_copies = False ) )
for ish in range ( self . n_shells ) :
G_loc [ ish ] . zero ( )
DOS = { sp : numpy . zeros ( [ n_om ] , numpy . float_ )
for sp in self . spin_block_names [ self . SO ] }
DOSproj = [ { } for ish in range ( self . n_shells ) ]
DOSproj_orb = [ { } for ish in range ( self . n_shells ) ]
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for ish in range ( self . n_shells ) :
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for sp in self . spin_block_names [ self . SO ] :
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dim = self . shells [ ish ] [ ' dim ' ]
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DOSproj [ ish ] [ sp ] = numpy . zeros ( [ n_om ] , numpy . float_ )
DOSproj_orb [ ish ] [ sp ] = numpy . zeros (
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[ n_om , dim , dim ] , numpy . complex_ )
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ikarray = numpy . array ( range ( self . n_k ) )
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for ik in mpi . slice_array ( ikarray ) :
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G_latt_w = self . lattice_gf (
ik = ik , mu = mu , iw_or_w = " w " , broadening = broadening , mesh = mesh , with_Sigma = with_Sigma , with_dc = with_dc )
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G_latt_w * = self . bz_weights [ ik ]
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# Non-projected DOS
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for iom in range ( n_om ) :
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for bname , gf in G_latt_w :
DOS [ bname ] [ iom ] - = gf . data [ iom , : , : ] . imag . trace ( ) / \
numpy . pi
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# Projected DOS:
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for ish in range ( self . n_shells ) :
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tmp = G_loc [ ish ] . copy ( )
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for ir in range ( self . n_parproj [ ish ] ) :
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for bname , gf in tmp :
tmp [ bname ] << self . downfold ( ik , ish , bname , G_latt_w [
bname ] , gf , shells = ' all ' , ir = ir )
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G_loc [ ish ] + = tmp
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# Collect data from mpi:
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for bname in DOS :
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DOS [ bname ] = mpi . all_reduce (
mpi . world , DOS [ bname ] , lambda x , y : x + y )
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for ish in range ( self . n_shells ) :
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G_loc [ ish ] << mpi . all_reduce (
mpi . world , G_loc [ ish ] , lambda x , y : x + y )
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mpi . barrier ( )
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# Symmetrize and rotate to local coord. system if needed:
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if self . symm_op != 0 :
G_loc = self . symmpar . symmetrize ( G_loc )
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if self . use_rotations :
for ish in range ( self . n_shells ) :
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for bname , gf in G_loc [ ish ] :
G_loc [ ish ] [ bname ] << self . rotloc (
ish , gf , direction = ' toLocal ' , shells = ' all ' )
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# G_loc can now also be used to look at orbitally-resolved quantities
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for ish in range ( self . n_shells ) :
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for bname , gf in G_loc [ ish ] :
for iom in range ( n_om ) :
DOSproj [ ish ] [ bname ] [ iom ] - = gf . data [ iom ,
: , : ] . imag . trace ( ) / numpy . pi
DOSproj_orb [ ish ] [ bname ] [
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: , : , : ] + = ( 1.0 j * ( gf - gf . conjugate ( ) . transpose ( ) ) / 2.0 / numpy . pi ) . data [ : , : , : ]
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# Write to files
if save_to_file and mpi . is_master_node ( ) :
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for sp in self . spin_block_names [ self . SO ] :
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f = open ( ' DOS_parproj_ %s .dat ' % sp , ' w ' )
for iom in range ( n_om ) :
f . write ( " %s %s \n " % ( om_mesh [ iom ] , DOS [ sp ] [ iom ] ) )
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f . close ( )
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# Partial
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for ish in range ( self . n_shells ) :
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f = open ( ' DOS_parproj_ %s _proj %s .dat ' % ( sp , ish ) , ' w ' )
for iom in range ( n_om ) :
f . write ( " %s %s \n " %
( om_mesh [ iom ] , DOSproj [ ish ] [ sp ] [ iom ] ) )
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f . close ( )
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# Orbitally-resolved
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for i in range ( self . shells [ ish ] [ ' dim ' ] ) :
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for j in range ( i , self . shells [ ish ] [ ' dim ' ] ) :
f = open ( ' DOS_parproj_ ' + sp + ' _proj ' + str ( ish ) +
' _ ' + str ( i ) + ' _ ' + str ( j ) + ' .dat ' , ' w ' )
for iom in range ( n_om ) :
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f . write ( " %s %s %s \n " % (
om_mesh [ iom ] , DOSproj_orb [ ish ] [ sp ] [ iom , i , j ] . real , DOSproj_orb [ ish ] [ sp ] [ iom , i , j ] . imag ) )
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f . close ( )
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return DOS , DOSproj , DOSproj_orb
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# Uses .data of only GfReFreq objects.
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def spaghettis ( self , broadening = None , plot_shift = 0.0 , plot_range = None , ishell = None , mu = None , save_to_file = ' Akw_ ' ) :
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"""
Calculates the correlated band structure using a real - frequency self energy .
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Parameters
- - - - - - - - - -
mu : double , optional
Chemical potential , overrides the one stored in the hdf5 archive .
broadening : double , optional
Lorentzian broadening of the spectra . If not given , standard value of lattice_gf is used .
plot_shift : double , optional
Offset for each A ( k , w ) for stacked plotting of spectra .
plot_range : list of double , optional
Sets the energy window for plotting to ( plot_range [ 0 ] , plot_range [ 1 ] ) . If not provided , the energy mesh of the self energy is used .
ishell : integer , optional
Contains the index of the shell on which the spectral function is projected . If ishell = None , the total spectrum without projection is calculated .
save_to_file : string , optional
Filename where the spectra are stored .
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Returns
- - - - - - -
Akw : Dict of numpy arrays
Data as it is also written to the files .
"""
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assert hasattr (
self , " Sigma_imp_w " ) , " spaghettis: Set Sigma_imp_w first. "
things_to_read = [ ' n_k ' , ' n_orbitals ' , ' proj_mat ' ,
' hopping ' , ' n_parproj ' , ' proj_mat_all ' ]
value_read = self . read_input_from_hdf (
subgrp = self . bands_data , things_to_read = things_to_read )
if not value_read :
return value_read
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if ishell is not None :
things_to_read = [ ' rot_mat_all ' , ' rot_mat_all_time_inv ' ]
value_read = self . read_input_from_hdf (
subgrp = self . parproj_data , things_to_read = things_to_read )
if not value_read :
return value_read
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if mu is None :
mu = self . chemical_potential
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spn = self . spin_block_names [ self . SO ]
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mesh = [ x . real for x in self . Sigma_imp_w [ 0 ] . mesh ]
n_om = len ( mesh )
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if plot_range is None :
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om_minplot = mesh [ 0 ] - 0.001
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om_maxplot = mesh [ n_om - 1 ] + 0.001
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else :
om_minplot = plot_range [ 0 ]
om_maxplot = plot_range [ 1 ]
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if ishell is None :
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Akw = { sp : numpy . zeros ( [ self . n_k , n_om ] , numpy . float_ )
for sp in spn }
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else :
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Akw = { sp : numpy . zeros (
[ self . shells [ ishell ] [ ' dim ' ] , self . n_k , n_om ] , numpy . float_ ) for sp in spn }
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if not ishell is None :
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gf_struct_parproj = [
( sp , range ( self . shells [ ishell ] [ ' dim ' ] ) ) for sp in spn ]
G_loc = BlockGf ( name_block_generator = [ ( block , GfReFreq ( indices = inner , mesh = self . Sigma_imp_w [ 0 ] . mesh ) )
for block , inner in gf_struct_parproj ] , make_copies = False )
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G_loc . zero ( )
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ikarray = numpy . array ( range ( self . n_k ) )
for ik in mpi . slice_array ( ikarray ) :
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G_latt_w = self . lattice_gf (
ik = ik , mu = mu , iw_or_w = " w " , broadening = broadening )
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if ishell is None :
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# Non-projected A(k,w)
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for iom in range ( n_om ) :
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if ( mesh [ iom ] > om_minplot ) and ( mesh [ iom ] < om_maxplot ) :
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for bname , gf in G_latt_w :
Akw [ bname ] [ ik , iom ] + = gf . data [ iom , : ,
: ] . imag . trace ( ) / ( - 1.0 * numpy . pi )
# shift Akw for plotting stacked k-resolved eps(k)
# curves
Akw [ bname ] [ ik , iom ] + = ik * plot_shift
else : # ishell not None
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# Projected A(k,w):
G_loc . zero ( )
tmp = G_loc . copy ( )
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for ir in range ( self . n_parproj [ ishell ] ) :
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for bname , gf in tmp :
tmp [ bname ] << self . downfold ( ik , ishell , bname , G_latt_w [
bname ] , gf , shells = ' all ' , ir = ir )
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G_loc + = tmp
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# Rotate to local frame
if self . use_rotations :
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for bname , gf in G_loc :
G_loc [ bname ] << self . rotloc (
ishell , gf , direction = ' toLocal ' , shells = ' all ' )
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for iom in range ( n_om ) :
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if ( mesh [ iom ] > om_minplot ) and ( mesh [ iom ] < om_maxplot ) :
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for ish in range ( self . shells [ ishell ] [ ' dim ' ] ) :
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for sp in spn :
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Akw [ sp ] [ ish , ik , iom ] = G_loc [ sp ] . data [
iom , ish , ish ] . imag / ( - 1.0 * numpy . pi )
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# Collect data from mpi
for sp in spn :
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Akw [ sp ] = mpi . all_reduce ( mpi . world , Akw [ sp ] , lambda x , y : x + y )
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mpi . barrier ( )
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if save_to_file and mpi . is_master_node ( ) :
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if ishell is None :
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for sp in spn : # loop over GF blocs:
# Open file for storage:
f = open ( save_to_file + sp + ' .dat ' , ' w ' )
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for ik in range ( self . n_k ) :
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for iom in range ( n_om ) :
if ( mesh [ iom ] > om_minplot ) and ( mesh [ iom ] < om_maxplot ) :
if plot_shift > 0.0001 :
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f . write ( ' %s %s \n ' %
( mesh [ iom ] , Akw [ sp ] [ ik , iom ] ) )
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else :
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f . write ( ' %s %s %s \n ' %
( ik , mesh [ iom ] , Akw [ sp ] [ ik , iom ] ) )
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f . write ( ' \n ' )
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f . close ( )
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else : # ishell is not None
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for sp in spn :
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for ish in range ( self . shells [ ishell ] [ ' dim ' ] ) :
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# Open file for storage:
f = open ( save_to_file + str ( ishell ) + ' _ ' +
sp + ' _proj ' + str ( ish ) + ' .dat ' , ' w ' )
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for ik in range ( self . n_k ) :
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for iom in range ( n_om ) :
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if ( mesh [ iom ] > om_minplot ) and ( mesh [ iom ] < om_maxplot ) :
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if plot_shift > 0.0001 :
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f . write ( ' %s %s \n ' % (
mesh [ iom ] , Akw [ sp ] [ ish , ik , iom ] ) )
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else :
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f . write ( ' %s %s %s \n ' % (
ik , mesh [ iom ] , Akw [ sp ] [ ish , ik , iom ] ) )
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f . write ( ' \n ' )
f . close ( )
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return Akw
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def partial_charges ( self , beta = 40 , mu = None , with_Sigma = True , with_dc = True ) :
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"""
Calculates the orbitally - resolved density matrix for all the orbitals considered in the input , consistent with
the definition of Wien2k . Hence , ( possibly non - orthonormal ) projectors have to be provided in the partial projectors subgroup of
the hdf5 archive .
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Parameters
- - - - - - - - - -
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with_Sigma : boolean , optional
If True , the self energy is used for the calculation . If false , partial charges are calculated without self - energy correction .
beta : double , optional
In case the self - energy correction is not used , the inverse temperature where the calculation should be done has to be given here .
mu : double , optional
Chemical potential , overrides the one stored in the hdf5 archive .
with_dc : boolean , optional
If True the double counting correction is used .
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Returns
- - - - - - -
dens_mat : list of numpy array
A list of density matrices projected to all shells provided in the input .
"""
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things_to_read = [ ' dens_mat_below ' , ' n_parproj ' ,
' proj_mat_all ' , ' rot_mat_all ' , ' rot_mat_all_time_inv ' ]
value_read = self . read_input_from_hdf (
subgrp = self . parproj_data , things_to_read = things_to_read )
if not value_read :
return value_read
if self . symm_op :
self . symmpar = Symmetry ( self . hdf_file , subgroup = self . symmpar_data )
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spn = self . spin_block_names [ self . SO ]
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ntoi = self . spin_names_to_ind [ self . SO ]
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# Density matrix in the window
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self . dens_mat_window = [ [ numpy . zeros ( [ self . shells [ ish ] [ ' dim ' ] , self . shells [ ish ] [ ' dim ' ] ] , numpy . complex_ )
for ish in range ( self . n_shells ) ]
for isp in range ( len ( spn ) ) ]
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# Set up G_loc
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gf_struct_parproj = [ [ ( sp , range ( self . shells [ ish ] [ ' dim ' ] ) ) for sp in spn ]
for ish in range ( self . n_shells ) ]
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if with_Sigma :
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G_loc = [ BlockGf ( name_block_generator = [ ( block , GfImFreq ( indices = inner , mesh = self . Sigma_imp_iw [ 0 ] . mesh ) )
for block , inner in gf_struct_parproj [ ish ] ] , make_copies = False )
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for ish in range ( self . n_shells ) ]
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beta = self . Sigma_imp_iw [ 0 ] . mesh . beta
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else :
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G_loc = [ BlockGf ( name_block_generator = [ ( block , GfImFreq ( indices = inner , beta = beta ) )
for block , inner in gf_struct_parproj [ ish ] ] , make_copies = False )
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for ish in range ( self . n_shells ) ]
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for ish in range ( self . n_shells ) :
G_loc [ ish ] . zero ( )
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ikarray = numpy . array ( range ( self . n_k ) )
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for ik in mpi . slice_array ( ikarray ) :
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G_latt_iw = self . lattice_gf (
ik = ik , mu = mu , iw_or_w = " iw " , beta = beta , with_Sigma = with_Sigma , with_dc = with_dc )
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G_latt_iw * = self . bz_weights [ ik ]
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for ish in range ( self . n_shells ) :
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tmp = G_loc [ ish ] . copy ( )
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for ir in range ( self . n_parproj [ ish ] ) :
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for bname , gf in tmp :
tmp [ bname ] << self . downfold ( ik , ish , bname , G_latt_iw [
bname ] , gf , shells = ' all ' , ir = ir )
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G_loc [ ish ] + = tmp
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# Collect data from mpi:
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for ish in range ( self . n_shells ) :
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G_loc [ ish ] << mpi . all_reduce (
mpi . world , G_loc [ ish ] , lambda x , y : x + y )
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mpi . barrier ( )
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# Symmetrize and rotate to local coord. system if needed:
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if self . symm_op != 0 :
G_loc = self . symmpar . symmetrize ( G_loc )
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if self . use_rotations :
for ish in range ( self . n_shells ) :
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for bname , gf in G_loc [ ish ] :
G_loc [ ish ] [ bname ] << self . rotloc (
ish , gf , direction = ' toLocal ' , shells = ' all ' )
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for ish in range ( self . n_shells ) :
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isp = 0
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for bname , gf in G_loc [ ish ] :
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self . dens_mat_window [ isp ] [ ish ] = G_loc [ ish ] . density ( ) [ bname ]
isp + = 1
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# Add density matrices to get the total:
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dens_mat = [ [ self . dens_mat_below [ ntoi [ spn [ isp ] ] ] [ ish ] + self . dens_mat_window [ isp ] [ ish ]
for ish in range ( self . n_shells ) ]
for isp in range ( len ( spn ) ) ]
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return dens_mat
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def print_hamiltonian ( self ) :
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"""
Prints the Kohn - Sham Hamiltonian to the text files hamup . dat and hamdn . dat ( no spin orbit - coupling ) , or to ham . dat ( with spin - orbit coupling ) .
"""
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if self . SP == 1 and self . SO == 0 :
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f1 = open ( ' hamup.dat ' , ' w ' )
f2 = open ( ' hamdn.dat ' , ' w ' )
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for ik in range ( self . n_k ) :
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for i in range ( self . n_orbitals [ ik , 0 ] ) :
f1 . write ( ' %s %s \n ' %
( ik , self . hopping [ ik , 0 , i , i ] . real ) )
for i in range ( self . n_orbitals [ ik , 1 ] ) :
f2 . write ( ' %s %s \n ' %
( ik , self . hopping [ ik , 1 , i , i ] . real ) )
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f1 . write ( ' \n ' )
f2 . write ( ' \n ' )
f1 . close ( )
f2 . close ( )
else :
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f = open ( ' ham.dat ' , ' w ' )
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for ik in range ( self . n_k ) :
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for i in range ( self . n_orbitals [ ik , 0 ] ) :
f . write ( ' %s %s \n ' %
( ik , self . hopping [ ik , 0 , i , i ] . real ) )
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f . write ( ' \n ' )
f . close ( )
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# ----------------- transport -----------------------
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def read_transport_input_from_hdf ( self ) :
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r """
Reads the data for transport calculations from the hdf5 archive .
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"""
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thingstoread = [ ' band_window_optics ' , ' velocities_k ' ]
self . read_input_from_hdf (
subgrp = self . transp_data , things_to_read = thingstoread )
thingstoread = [ ' band_window ' , ' lattice_angles ' , ' lattice_constants ' ,
' lattice_type ' , ' n_symmetries ' , ' rot_symmetries ' ]
self . read_input_from_hdf (
subgrp = self . misc_data , things_to_read = thingstoread )
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def cellvolume ( self , lattice_type , lattice_constants , latticeangle ) :
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r """
Determines the conventional und primitive unit cell volumes .
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Parameters
- - - - - - - - - -
lattice_type : string
Lattice type according to the Wien2k convention ( P , F , B , R , H , CXY , CYZ , CXZ ) .
lattice_constants : list of double
Lattice constants ( a , b , c ) .
lattice angles : list of double
Lattice angles ( : math : ` \alpha , \beta , \gamma ` ) .
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Returns
- - - - - - -
vol_c : double
Conventional unit cell volume .
vol_p : double
Primitive unit cell volume .
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"""
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a = lattice_constants [ 0 ]
b = lattice_constants [ 1 ]
c = lattice_constants [ 2 ]
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c_al = numpy . cos ( latticeangle [ 0 ] )
c_be = numpy . cos ( latticeangle [ 1 ] )
c_ga = numpy . cos ( latticeangle [ 2 ] )
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vol_c = a * b * c * \
numpy . sqrt ( 1 + 2 * c_al * c_be * c_ga -
c_al * * 2 - c_be * * 2 - c_ga * * 2 )
det = { " P " : 1 , " F " : 4 , " B " : 2 , " R " : 3 ,
" H " : 1 , " CXY " : 2 , " CYZ " : 2 , " CXZ " : 2 }
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vol_p = vol_c / det [ lattice_type ]
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return vol_c , vol_p
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# Uses .data of only GfReFreq objects.
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def transport_distribution ( self , beta , directions = [ ' xx ' ] , energy_window = None , Om_mesh = [ 0.0 ] , with_Sigma = False , n_om = None , broadening = 0.0 ) :
r """
Calculates the transport distribution
. . math : :
\Gamma_ { \alpha \beta } \left ( \omega + \Omega / 2 , \omega - \Omega / 2 \right ) = \frac { 1 } { V } \sum_k Tr \left ( v_ { k , \alpha } A_ { k } ( \omega + \Omega / 2 ) v_ { k , \beta } A_ { k } \left ( \omega - \Omega / 2 \right ) \right )
in the direction : math : ` \alpha \beta ` . The velocities : math : ` v_ { k } ` are read from the transport subgroup of the hdf5 archive .
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Parameters
- - - - - - - - - -
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beta : double
Inverse temperature : math : ` \beta ` .
directions : list of double , optional
: math : ` \alpha \beta ` e . g . : [ ' xx ' , ' yy ' , ' zz ' , ' xy ' , ' xz ' , ' yz ' ] .
energy_window : list of double , optional
Specifies the upper and lower limit of the frequency integration for : math : ` \Omega = 0.0 ` . The window is automatically enlarged by the largest : math : ` \Omega ` value ,
hence the integration is performed in the interval [ energy_window [ 0 ] - max ( Om_mesh ) , energy_window [ 1 ] + max ( Om_mesh ) ] .
Om_mesh : list of double , optional
: math : ` \Omega ` frequency mesh of the optical conductivity . For the conductivity and the Seebeck coefficient : math : ` \Omega = 0.0 ` has to be
part of the mesh . In the current version Om_mesh is repined to the mesh provided by the self - energy ! The actual mesh is printed on the screen and stored as
member Om_mesh .
with_Sigma : boolean , optional
Determines whether the calculation is performed with or without self energy . If this parameter is set to False the self energy is set to zero ( i . e . the DFT band
structure : math : ` A ( k , \omega ) ` is used ) . Note : For with_Sigma = False it is necessary to specify the parameters energy_window , n_om and broadening .
n_om : integer , optional
Number of equidistant frequency points in the interval [ energy_window [ 0 ] - max ( Om_mesh ) , energy_window [ 1 ] + max ( Om_mesh ) ] . This parameters is only used if
with_Sigma = False .
broadening : double , optional
Lorentzian broadening . It is necessary to specify the boradening if with_Sigma = False , otherwise this parameter can be set to 0.0 .
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"""
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# Check if wien converter was called and read transport subgroup form
# hdf file
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if mpi . is_master_node ( ) :
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ar = HDFArchive ( self . hdf_file , ' r ' )
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if not ( self . transp_data in ar ) :
raise IOError , " transport_distribution: No %s subgroup in hdf file found! Call convert_transp_input first. " % self . transp_data
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# check if outputs file was converted
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if not ( ' n_symmetries ' in ar [ ' dft_misc_input ' ] ) :
raise IOError , " transport_distribution: n_symmetries missing. Check if case.outputs file is present and call convert_misc_input() or convert_dft_input(). "
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self . read_transport_input_from_hdf ( )
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if mpi . is_master_node ( ) :
# k-dependent-projections.
assert self . k_dep_projection == 1 , " transport_distribution: k dependent projection is not implemented! "
# positive Om_mesh
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assert all (
Om > = 0.0 for Om in Om_mesh ) , " transport_distribution: Om_mesh should not contain negative values! "
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# Check if energy_window is sufficiently large and correct
if ( energy_window [ 0 ] > = energy_window [ 1 ] or energy_window [ 0 ] > = 0 or energy_window [ 1 ] < = 0 ) :
assert 0 , " transport_distribution: energy_window wrong! "
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if ( abs ( self . fermi_dis ( energy_window [ 0 ] , beta ) * self . fermi_dis ( - energy_window [ 0 ] , beta ) ) > 1e-5
or abs ( self . fermi_dis ( energy_window [ 1 ] , beta ) * self . fermi_dis ( - energy_window [ 1 ] , beta ) ) > 1e-5 ) :
mpi . report (
" \n #################################################################### " )
mpi . report (
" transport_distribution: WARNING - energy window might be too narrow! " )
mpi . report (
" #################################################################### \n " )
# up and down are equivalent if SP = 0
n_inequiv_spin_blocks = self . SP + 1 - self . SO
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self . directions = directions
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dir_to_int = { ' x ' : 0 , ' y ' : 1 , ' z ' : 2 }
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# calculate A(k,w)
#######################################
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# Define mesh for Green's function and in the specified energy window
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if ( with_Sigma == True ) :
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self . omega = numpy . array ( [ round ( x . real , 12 )
for x in self . Sigma_imp_w [ 0 ] . mesh ] )
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mesh = None
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mu = self . chemical_potential
n_om = len ( self . omega )
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mpi . report ( " Using omega mesh provided by Sigma! " )
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if energy_window is not None :
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# Find according window in Sigma mesh
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ioffset = numpy . sum (
self . omega < energy_window [ 0 ] - max ( Om_mesh ) )
self . omega = self . omega [ numpy . logical_and ( self . omega > = energy_window [
0 ] - max ( Om_mesh ) , self . omega < = energy_window [ 1 ] + max ( Om_mesh ) ) ]
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n_om = len ( self . omega )
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# Truncate Sigma to given omega window
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# In the future there should be an option in gf to manipulate the mesh (e.g. truncate) directly.
# For now we stick with this:
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for icrsh in range ( self . n_corr_shells ) :
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Sigma_save = self . Sigma_imp_w [ icrsh ] . copy ( )
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spn = self . spin_block_names [ self . corr_shells [ icrsh ] [ ' SO ' ] ]
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glist = lambda : [ GfReFreq ( indices = inner , window = ( self . omega [
0 ] , self . omega [ - 1 ] ) , n_points = n_om ) for block , inner in self . gf_struct_sumk [ icrsh ] ]
self . Sigma_imp_w [ icrsh ] = BlockGf (
name_list = spn , block_list = glist ( ) , make_copies = False )
for i , g in self . Sigma_imp_w [ icrsh ] :
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for iL in g . indices [ 0 ] :
for iR in g . indices [ 0 ] :
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for iom in xrange ( n_om ) :
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g . data [ iom , int ( iL ) , int ( iR ) ] = Sigma_save [
i ] . data [ ioffset + iom , int ( iL ) , int ( iR ) ]
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else :
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assert n_om is not None , " transport_distribution: Number of omega points (n_om) needed to calculate transport distribution! "
assert energy_window is not None , " transport_distribution: Energy window needed to calculate transport distribution! "
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assert broadening != 0.0 and broadening is not None , " transport_distribution: Broadening necessary to calculate transport distribution! "
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self . omega = numpy . linspace (
energy_window [ 0 ] - max ( Om_mesh ) , energy_window [ 1 ] + max ( Om_mesh ) , n_om )
mesh = [ energy_window [ 0 ] -
max ( Om_mesh ) , energy_window [ 1 ] + max ( Om_mesh ) , n_om ]
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mu = 0.0
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# Define mesh for optic conductivity
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d_omega = round ( numpy . abs ( self . omega [ 0 ] - self . omega [ 1 ] ) , 12 )
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iOm_mesh = numpy . array ( [ round ( ( Om / d_omega ) , 0 ) for Om in Om_mesh ] )
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self . Om_mesh = iOm_mesh * d_omega
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if mpi . is_master_node ( ) :
print " Chemical potential: " , mu
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print " Using n_om = %s points in the energy_window [ %s , %s ] " % ( n_om , self . omega [ 0 ] , self . omega [ - 1 ] ) ,
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print " where the omega vector is: "
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print self . omega
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print " Calculation requested for Omega mesh: " , numpy . array ( Om_mesh )
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print " Omega mesh automatically repined to: " , self . Om_mesh
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self . Gamma_w = { direction : numpy . zeros (
( len ( self . Om_mesh ) , n_om ) , dtype = numpy . float_ ) for direction in self . directions }
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# Sum over all k-points
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ikarray = numpy . array ( range ( self . n_k ) )
for ik in mpi . slice_array ( ikarray ) :
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# Calculate G_w for ik and initialize A_kw
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G_w = self . lattice_gf ( ik , mu , iw_or_w = " w " , beta = beta ,
broadening = broadening , mesh = mesh , with_Sigma = with_Sigma )
A_kw = [ numpy . zeros ( ( self . n_orbitals [ ik ] [ isp ] , self . n_orbitals [ ik ] [ isp ] , n_om ) , dtype = numpy . complex_ )
for isp in range ( n_inequiv_spin_blocks ) ]
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for isp in range ( n_inequiv_spin_blocks ) :
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# copy data from G_w (swapaxes is used to have omega in the 3rd
# dimension)
A_kw [ isp ] = copy . deepcopy ( G_w [ self . spin_block_names [ self . SO ] [
isp ] ] . data . swapaxes ( 0 , 1 ) . swapaxes ( 1 , 2 ) )
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# calculate A(k,w) for each frequency
for iw in xrange ( n_om ) :
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A_kw [ isp ] [ : , : , iw ] = - 1.0 / ( 2.0 * numpy . pi * 1 j ) * (
A_kw [ isp ] [ : , : , iw ] - numpy . conjugate ( numpy . transpose ( A_kw [ isp ] [ : , : , iw ] ) ) )
b_min = max ( self . band_window [ isp ] [
ik , 0 ] , self . band_window_optics [ isp ] [ ik , 0 ] )
b_max = min ( self . band_window [ isp ] [
ik , 1 ] , self . band_window_optics [ isp ] [ ik , 1 ] )
A_i = slice (
b_min - self . band_window [ isp ] [ ik , 0 ] , b_max - self . band_window [ isp ] [ ik , 0 ] + 1 )
v_i = slice ( b_min - self . band_window_optics [ isp ] [
ik , 0 ] , b_max - self . band_window_optics [ isp ] [ ik , 0 ] + 1 )
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# loop over all symmetries
for R in self . rot_symmetries :
# get transformed velocity under symmetry R
vel_R = copy . deepcopy ( self . velocities_k [ isp ] [ ik ] )
for nu1 in range ( self . band_window_optics [ isp ] [ ik , 1 ] - self . band_window_optics [ isp ] [ ik , 0 ] + 1 ) :
for nu2 in range ( self . band_window_optics [ isp ] [ ik , 1 ] - self . band_window_optics [ isp ] [ ik , 0 ] + 1 ) :
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vel_R [ nu1 ] [ nu2 ] [ : ] = numpy . dot (
R , vel_R [ nu1 ] [ nu2 ] [ : ] )
# calculate Gamma_w for each direction from the velocities
# vel_R and the spectral function A_kw
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for direction in self . directions :
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for iw in xrange ( n_om ) :
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for iq in range ( len ( self . Om_mesh ) ) :
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if ( iw + iOm_mesh [ iq ] > = n_om or self . omega [ iw ] < - self . Om_mesh [ iq ] + energy_window [ 0 ] or self . omega [ iw ] > self . Om_mesh [ iq ] + energy_window [ 1 ] ) :
continue
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self . Gamma_w [ direction ] [ iq , iw ] + = ( numpy . dot ( numpy . dot ( numpy . dot ( vel_R [ v_i , v_i , dir_to_int [ direction [ 0 ] ] ] ,
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A_kw [ isp ] [ A_i , A_i , int ( iw + iOm_mesh [ iq ] ) ] ) , vel_R [ v_i , v_i , dir_to_int [ direction [ 1 ] ] ] ) ,
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A_kw [ isp ] [ A_i , A_i , iw ] ) . trace ( ) . real * self . bz_weights [ ik ] )
for direction in self . directions :
self . Gamma_w [ direction ] = ( mpi . all_reduce ( mpi . world , self . Gamma_w [ direction ] , lambda x , y : x + y )
/ self . cellvolume ( self . lattice_type , self . lattice_constants , self . lattice_angles ) [ 1 ] / self . n_symmetries )
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def transport_coefficient ( self , direction , iq , n , beta , method = None ) :
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r """
Calculates the transport coefficient A_n in a given direction for a given : math : ` \Omega ` . The required members ( Gamma_w , directions , Om_mesh ) have to be obtained first
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by calling the function : meth : ` transport_distribution < dft . sumk_dft_tools . SumkDFTTools . transport_distribution > ` . For n > 0 A is set to NaN if : math : ` \Omega ` is not 0.0 .
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Parameters
- - - - - - - - - -
direction : string
: math : ` \alpha \beta ` e . g . : ' xx ' , ' yy ' , ' zz ' , ' xy ' , ' xz ' , ' yz ' .
iq : integer
Index of : math : ` \Omega ` point in the member Om_mesh .
n : integer
Number of the desired moment of the transport distribution .
beta : double
Inverse temperature : math : ` \beta ` .
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method : string
Integration method : cubic spline and scipy . integrate . quad ( ' quad ' ) , simpson rule ( ' simps ' ) , trapezoidal rule ( ' trapz ' ) , rectangular integration ( otherwise )
Note that the sampling points of the the self - energy are used !
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Returns
- - - - - - -
A : double
Transport coefficient .
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"""
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if not ( mpi . is_master_node ( ) ) :
return
assert hasattr (
self , ' Gamma_w ' ) , " transport_coefficient: Run transport_distribution first or load data from h5! "
if ( self . Om_mesh [ iq ] == 0.0 or n == 0.0 ) :
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A = 0.0
# setup the integrand
if ( self . Om_mesh [ iq ] == 0.0 ) :
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A_int = self . Gamma_w [ direction ] [ iq ] * ( self . fermi_dis (
self . omega , beta ) * self . fermi_dis ( - self . omega , beta ) ) * ( self . omega * beta ) * * n
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elif ( n == 0.0 ) :
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A_int = self . Gamma_w [ direction ] [ iq ] * ( self . fermi_dis ( self . omega , beta ) - self . fermi_dis (
self . omega + self . Om_mesh [ iq ] , beta ) ) / ( self . Om_mesh [ iq ] * beta )
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# w-integration
if method == ' quad ' :
# quad on interpolated w-points with cubic spline
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A_int_interp = interp1d ( self . omega , A_int , kind = ' cubic ' )
A = quad ( A_int_interp , min ( self . omega ) , max ( self . omega ) ,
epsabs = 1.0e-12 , epsrel = 1.0e-12 , limit = 500 )
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A = A [ 0 ]
elif method == ' simps ' :
# simpson rule for w-grid
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A = simps ( A_int , self . omega )
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elif method == ' trapz ' :
# trapezoidal rule for w-grid
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A = numpy . trapz ( A_int , self . omega )
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else :
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# rectangular integration for w-grid (orignal implementation)
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d_w = self . omega [ 1 ] - self . omega [ 0 ]
for iw in xrange ( self . Gamma_w [ direction ] . shape [ 1 ] ) :
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A + = A_int [ iw ] * d_w
A = A * numpy . pi * ( 2.0 - self . SP )
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else :
A = numpy . nan
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return A
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def conductivity_and_seebeck ( self , beta , method = None ) :
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r """
Calculates the Seebeck coefficient and the optical conductivity by calling
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: meth : ` transport_coefficient < dft . sumk_dft_tools . SumkDFTTools . transport_coefficient > ` .
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The required members ( Gamma_w , directions , Om_mesh ) have to be obtained first by calling the function
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: meth : ` transport_distribution < dft . sumk_dft_tools . SumkDFTTools . transport_distribution > ` .
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Parameters
- - - - - - - - - -
beta : double
Inverse temperature : math : ` \beta ` .
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Returns
- - - - - - -
optic_cond : dictionary of double vectors
Optical conductivity in each direction and frequency given by Om_mesh .
seebeck : dictionary of double
Seebeck coefficient in each direction . If zero is not present in Om_mesh the Seebeck coefficient is set to NaN .
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"""
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if not ( mpi . is_master_node ( ) ) :
return
assert hasattr (
self , ' Gamma_w ' ) , " conductivity_and_seebeck: Run transport_distribution first or load data from h5! "
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n_q = self . Gamma_w [ self . directions [ 0 ] ] . shape [ 0 ]
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A0 = { direction : numpy . full ( ( n_q , ) , numpy . nan )
for direction in self . directions }
A1 = { direction : numpy . full ( ( n_q , ) , numpy . nan )
for direction in self . directions }
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self . seebeck = { direction : numpy . nan for direction in self . directions }
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self . optic_cond = { direction : numpy . full (
( n_q , ) , numpy . nan ) for direction in self . directions }
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for direction in self . directions :
for iq in xrange ( n_q ) :
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A0 [ direction ] [ iq ] = self . transport_coefficient (
direction , iq = iq , n = 0 , beta = beta , method = method )
A1 [ direction ] [ iq ] = self . transport_coefficient (
direction , iq = iq , n = 1 , beta = beta , method = method )
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print " A_0 in direction %s for Omega = %.2f %e a.u. " % ( direction , self . Om_mesh [ iq ] , A0 [ direction ] [ iq ] )
print " A_1 in direction %s for Omega = %.2f %e a.u. " % ( direction , self . Om_mesh [ iq ] , A1 [ direction ] [ iq ] )
if ~ numpy . isnan ( A1 [ direction ] [ iq ] ) :
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# Seebeck is overwritten if there is more than one Omega =
# 0 in Om_mesh
self . seebeck [ direction ] = - \
A1 [ direction ] [ iq ] / A0 [ direction ] [ iq ] * 86.17
self . optic_cond [ direction ] = beta * \
A0 [ direction ] * 10700.0 / numpy . pi
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for iq in xrange ( n_q ) :
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print " Conductivity in direction %s for Omega = %.2f %f x 10^4 Ohm^-1 cm^-1 " % ( direction , self . Om_mesh [ iq ] , self . optic_cond [ direction ] [ iq ] )
if not ( numpy . isnan ( A1 [ direction ] [ iq ] ) ) :
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print " Seebeck in direction %s for Omega = 0.00 %f x 10^(-6) V/K " % ( direction , self . seebeck [ direction ] )
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return self . optic_cond , self . seebeck
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def fermi_dis ( self , w , beta ) :
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r """
Fermi distribution .
. . math : :
f ( x ) = 1 / ( e ^ x + 1 ) .
Parameters
- - - - - - - - - -
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w : double
frequency
beta : double
inverse temperature
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Returns
- - - - - - -
f : double
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"""
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return 1.0 / ( numpy . exp ( w * beta ) + 1 )