# coding: utf8 # vim: set et sw=4 ts=4 fdm=indent nu cc=+1: from ase.lattice.tetragonal import SimpleTetragonalFactory from ase.visualize import view from ase.spacegroup import get_spacegroup from sprkkr.calculator import SPRKKR from msspec.calculator import MSSPEC, XRaySource from msspec.utils import * import numpy as np import logging import sys import os import glob logging.basicConfig(level=logging.DEBUG) logger = logging.getLogger(__name__) # Define a Perovskite Factory class class PerovskiteFactory(SimpleTetragonalFactory): bravais_basis = [[0, 0, 0.0], [0.5, 0.5, 0.5],[0.5, 0, 0], [0, 0.5, 0], [0.0, 0.0, 0.5]] element_basis = (0, 1, 2, 2, 2) ABO3 = Perovskite = PerovskiteFactory() # Generate the base STO cell a0 = 3.905 STO = Perovskite(('Sr', 'Ti', 'O'), latticeconstant={'a': a0, 'c/a': 1.}, size=(1,1,1)) prefix = "SrTiO3" if 'view' in sys.argv: view(STO) # ########## SPRKKR part if 'sprkkr' in sys.argv: # create a SPRKKR calculator calc = SPRKKR(label=f"{prefix}/{prefix}") # attach the atoms to the calculator object calc.set_atoms(STO) # Here is how to modify input file # calc.input.control_section.set(DATASET="Fe", ADSI="SCF", POTFIL="Fe.pot") # calc.input.tau_section.set(nktab=250) # launch kkrscf calc.get_potential_energy() # calc2 = SPRKKR(label="Fe/Fe", task="phagen") # calc2.set_atoms(Fe) # calc2.input.control_section.set(POTFIL="Fe.pot_new") # calc2.phagen() # # EXPORT POTENTIAL FOR PHAGEN # #change task and command calc.set_command('PHAGEN') # Change output file calc.set_outfile(f"{prefix}_phagen.out") #to change task we need to replace input file tempate calc.set_inpfile(f"{prefix}_phagen.inp") calc.input.control_section.set(DATASET="PHAGEN", ADSI="PHAGEN") #set potetential file to converged potential conv_potfile=os.path.join(calc.potfile+'_new') calc.set_potfile(conv_potfile) #run given task calc.phagen() # ######### MsSpec part if 'msspec' in sys.argv: ########################################################################### # Build the SrTiO3 cluster # ########################################################################### # We start by loading the potential since it updates info in the STO cell pot = SPRKKRPotential(STO, "SrTiO3/SrTiO3.pot_new", *glob.glob("SrTiO3/*PHAGEN.pot")) # tag each atom in the STO object to easily set the emitter in the # hemispherical_cluster function [atom.set('tag', ('Sr', 'Ti', 'O').index(atom.symbol)) for atom in STO] # Create a hemispherical cluster centered on a Ti emitter from the # STO primitive cell used in the SPRKKR step. # For this example we use 4 planes and the Ti emitter (tag #1) is # located in the 2nd plane (numbering starts at 0) cluster = hemispherical_cluster(STO, planes=4, emitter_plane=1, emitter_tag=1) # The created cluster is centered on the emitter atom, so defining # the absorber attribute is straight forward: cluster.absorber = get_atom_index(cluster, 0, 0, 0) ########################################################################### # Set up the PhotoElectron Diffraction calculator # ########################################################################### # Create the calculator calc = MSSPEC(spectroscopy='PED', algorithm='expansion', folder='PED') # minimalistic set of parameter for XPD scan calc.set_atoms(cluster) calc.source_parameters.energy = 700 calc.calculation_parameters.scattering_order = 2 # Run a polar scan with the default MuffinTin potential for Ti(2p3/2) data = calc.get_theta_scan(level='2p3/2') # Now we use the previously generated SPRKKR potential # and run the same calculation with appending the data to the previous one calc.tmatrix_parameters.potential = pot data = calc.get_theta_scan(level='2p3/2', data=data) # To better see the differences, plot the normalized signal on the # same graph # pick up previous data theta, muffintin_cs, sprkkr_cs = (data[0].theta.copy(), data[0].cross_section.copy(), data[1].cross_section.copy()) # divide by the max sprkkr_cs /= sprkkr_cs.max() muffintin_cs /= muffintin_cs.max() # add a new dataset with those values dset = data.add_dset('comparison') dset.add_columns(theta=theta, sprkkr=sprkkr_cs, muffintin=muffintin_cs) # add a view for this dataset view = dset.add_view('Comparison', title=r'Comparison of XPD polar scans for Ti(2p3/2)', xlabel=r'$\Theta (\degree$)', ylabel='Normalized Signal (a.u.)') view.select('theta', 'sprkkr', legend='With SPRKKR potential') view.select('theta', 'muffintin', legend='With internal MuffinTin potential') view.set_plot_options(autoscale=True) # Pop up the final result data.view() if len(sys.argv) <= 1: print("Please specify either 'sprkkr', 'msspec' keywords or both " "of them on the command line")