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.Version 9.0.0 of CUT3D
.(MPI version, prepared for a x86_64_linux_gnu9.2 computer)
.Copyright (C) 1998-2025 ABINIT group .
CUT3D comes with ABSOLUTELY NO WARRANTY.
It is free software, and you are welcome to redistribute it
under certain conditions (GNU General Public License,
see ~abinit/COPYING or http://www.gnu.org/copyleft/gpl.txt).
ABINIT is a project of the Universite Catholique de Louvain,
Corning Inc. and other collaborators, see ~abinit/doc/developers/contributors.txt .
Please read https://docs.abinit.org/theory/acknowledgments for suggested
acknowledgments of the ABINIT effort.
For more information, see https://www.abinit.org .
.Starting date : Mon 24 Feb 2020.
- ( at 16h16 )
What is the name of the 3D function (density, potential or wavef) file ?
=> Your 3D function file is: t65o_DS2_WFK
- Your file contains unformatted binary header + 3D data
===============================================================================
ECHO of the ABINIT file header
First record :
.codvsn,headform,fform = 9.0.0 80 2
Second record :
bantot,intxc,ixc,natom = 30 0 7 1
ngfft(1:3),nkpt = 24 24 24 3
nspden,nspinor = 1 1
nsppol,nsym,npsp,ntypat = 1 8 1 1
occopt,pertcase,usepaw = 7 0 0
ecut,ecutdg,ecutsm = 3.0000000000E+00 3.0000000000E+00 0.0000000000E+00
ecut_eff = 3.0000000000E+00
qptn(1:3) = 0.0000000000E+00 0.0000000000E+00 0.0000000000E+00
rprimd(1:3,1) = 1.4000000000E+01 0.0000000000E+00 0.0000000000E+00
rprimd(1:3,2) = 0.0000000000E+00 1.4001000000E+01 0.0000000000E+00
rprimd(1:3,3) = 0.0000000000E+00 0.0000000000E+00 1.4002000000E+01
stmbias,tphysel,tsmear = 0.0000000000E+00 0.0000000000E+00 1.0000000000E-03
Third record :
istwfk= 1 1 1
nband = 10 10 10
npwarr= 691 682 672
so_psp= 1
symafm=
1 1 1 1 1 1 1 1
symrel=
1 0 0 0 1 0 0 0 1 -1 0 0 0 -1 0 0 0 -1
-1 0 0 0 1 0 0 0 -1 1 0 0 0 -1 0 0 0 1
-1 0 0 0 -1 0 0 0 1 1 0 0 0 1 0 0 0 -1
1 0 0 0 -1 0 0 0 -1 -1 0 0 0 1 0 0 0 1
type = 1
kptns = (max 50 k-points will be written)
0.000000E+00 0.000000E+00 0.000000E+00
5.000000E-01 0.000000E+00 0.000000E+00
5.000000E-01 5.000000E-01 5.000000E-01
wtk =
1.00 1.00 1.00
occ =
2.00 1.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00
2.00 1.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00
2.00 1.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00 0.00
tnons =
0.000000 0.000000 0.000000 0.400000 -0.400000 -0.200000
0.400000 0.000000 -0.200000 0.000000 -0.400000 0.000000
0.400000 -0.400000 0.000000 0.000000 0.000000 -0.200000
0.000000 -0.400000 -0.200000 0.400000 0.000000 0.000000
znucl= 13.00
Pseudopotential info :
title=Goedecker-Teter-Hutter Tue May 28 09:24:05 EDT 1996
znuclpsp= 13.00, zionpsp= 3.00, pspso= 0, pspdat=960528, pspcod= 2, pspxc= 1
lmnmax = 3
Last record :
residm,etot,fermie= 9.983593E-17 -1.912169624853E+00 -7.655537E-02
xred =
2.000000E-01 3.000000E-01 4.000000E-01
End the ECHO of the ABINIT file header
===============================================================================
===========================================================
ECHO important input variables ...
Dimensional primitive vectors (ABINIT equivalent: rprimd):
1.400000E+01 0.000000E+00 0.000000E+00
0.000000E+00 1.400100E+01 0.000000E+00
0.000000E+00 0.000000E+00 1.400200E+01
Grid density (ABINIT equivalent: ngfft): 24 24 24
Number of atoms : 1
Number of atomic types: 1
# Atomic positions (cartesian coordinates - Bohr)
1 2.800000E+00 4.200300E+00 5.600800E+00
This file is a WF file.
For which k-points? (1 to 3)
=> Your k-point is : 1
For which band ? (1 to 10)
=> Your band number is : 1
=> Your spin polarisation number is : 1
Do you want to analyze a GW wavefunction? (1=yes,0=no)
=> Your choice is : 0
Do you want the atomic analysis for this state :
(kpt,band)= ( 1 1)?
If yes, enter the radius of the atomic spheres, in bohr
If no, enter 0
You entered ratsph= 7.00000000 Bohr
Atomic sphere analysis
wffile : kpgmax, bessargmax, nradint = 1.732051E+00 7.620000E+01 762
Angular analysis (real spherical harmonics)
Atom # 1 is Al, in-sphere charge = 0.996233
l=0, charge= 0.996164, m=-l,l splitting: 0.996
l=1, charge= 0.000000, m=-l,l splitting: 0.000 0.000 0.000
l=2, charge= 0.000000, m=-l,l splitting: 0.000 0.000 0.000 0.000 0.000
l=3, charge= 0.000000, m=-l,l splitting: 0.000 0.000 0.000 0.000 0.000 0.000 0.000
l=4, charge= 0.000069, m=-l,l splitting: 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000
Sum of angular contributions for all atomic spheres
l=0, charge = 0.996164 proportion = 0.999931
l=1, charge = 0.000000 proportion = 0.000000
l=2, charge = 0.000000 proportion = 0.000000
l=3, charge = 0.000000 proportion = 0.000000
l=4, charge = 0.000069 proportion = 0.000069
Total over all atoms and l=0 to 4 : 0.996233
Charge in the sphere around each atom
Atom number 1 : charge = 0.99637180
3D wave function was read. Ready for further treatment.
===========================================================
What is your choice ? Type:
0 => exit to k-point / band / spin-pol loop
1 => 3D formatted real and imaginary data
(output the bare 3D data - two column,R,I)
2 => 3D formatted real data
(output the bare 3D data - one column)
3 => 3D formatted imaginary data
(output the bare 3D data - one column)
4 => 3D indexed real and imaginary data
(3D data, preceeded by 3D index)
5 => 3D indexed real data
(bare 3D data, preceeded by 3D index)
6 => 3D indexed imaginary data
(bare 3D data, preceeded by 3D index)
7 => 3D Data Explorer formatted data
(Real file and Imaginary file)
8 => 3D Data Explorer formatted data
(Only the Real file)
9 => 3D Data Explorer formatted data
(Only the Imaginary file)
10 => 3D Data Explorer formatted data and position files
11 => XCrysden formatted data (norm of wf) and position files
12 => NetCDF data and position file
13 => XCrysden/VENUS wavefunction (real part of data)
14 => Gaussian/cube wavefunction module
Your choice is 0
Exit inner loop
Task 0 has been done !
Run interpolation again? (1=default=yes,0=no)
For which k-points? (1 to 3)
=> Your k-point is : 1
For which band ? (1 to 10)
=> Your band number is : 2
=> Your spin polarisation number is : 1
Do you want to analyze a GW wavefunction? (1=yes,0=no)
=> Your choice is : 0
Do you want the atomic analysis for this state :
(kpt,band)= ( 1 2)?
If yes, enter the radius of the atomic spheres, in bohr
If no, enter 0
You entered ratsph= 7.00000000 Bohr
Atomic sphere analysis
wffile : kpgmax, bessargmax, nradint = 1.732051E+00 7.620000E+01 762
Angular analysis (real spherical harmonics)
Atom # 1 is Al, in-sphere charge = 0.987234
l=0, charge= 0.000000, m=-l,l splitting: 0.000
l=1, charge= 0.985080, m=-l,l splitting: 0.000 0.985 0.000
l=2, charge= 0.000000, m=-l,l splitting: 0.000 0.000 0.000 0.000 0.000
l=3, charge= 0.002154, m=-l,l splitting: 0.000 0.000 0.000 0.002 0.000 0.000 0.000
l=4, charge= 0.000000, m=-l,l splitting: 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000
Sum of angular contributions for all atomic spheres
l=0, charge = 0.000000 proportion = 0.000000
l=1, charge = 0.985080 proportion = 0.997818
l=2, charge = 0.000000 proportion = 0.000000
l=3, charge = 0.002154 proportion = 0.002182
l=4, charge = 0.000000 proportion = 0.000000
Total over all atoms and l=0 to 4 : 0.987234
Charge in the sphere around each atom
Atom number 1 : charge = 0.98730916
3D wave function was read. Ready for further treatment.
===========================================================
What is your choice ? Type:
0 => exit to k-point / band / spin-pol loop
1 => 3D formatted real and imaginary data
(output the bare 3D data - two column,R,I)
2 => 3D formatted real data
(output the bare 3D data - one column)
3 => 3D formatted imaginary data
(output the bare 3D data - one column)
4 => 3D indexed real and imaginary data
(3D data, preceeded by 3D index)
5 => 3D indexed real data
(bare 3D data, preceeded by 3D index)
6 => 3D indexed imaginary data
(bare 3D data, preceeded by 3D index)
7 => 3D Data Explorer formatted data
(Real file and Imaginary file)
8 => 3D Data Explorer formatted data
(Only the Real file)
9 => 3D Data Explorer formatted data
(Only the Imaginary file)
10 => 3D Data Explorer formatted data and position files
11 => XCrysden formatted data (norm of wf) and position files
12 => NetCDF data and position file
13 => XCrysden/VENUS wavefunction (real part of data)
14 => Gaussian/cube wavefunction module
Your choice is 0
Exit inner loop
Task 0 has been done !
Run interpolation again? (1=default=yes,0=no)
For which k-points? (1 to 3)
=> Your k-point is : 1
For which band ? (1 to 10)
=> Your band number is : 3
=> Your spin polarisation number is : 1
Do you want to analyze a GW wavefunction? (1=yes,0=no)
=> Your choice is : 0
Do you want the atomic analysis for this state :
(kpt,band)= ( 1 3)?
If yes, enter the radius of the atomic spheres, in bohr
If no, enter 0
You entered ratsph= 7.00000000 Bohr
Atomic sphere analysis
wffile : kpgmax, bessargmax, nradint = 1.732051E+00 7.620000E+01 762
Angular analysis (real spherical harmonics)
Atom # 1 is Al, in-sphere charge = 0.987239
l=0, charge= 0.000000, m=-l,l splitting: 0.000
l=1, charge= 0.985084, m=-l,l splitting: 0.985 0.000 0.000
l=2, charge= 0.000000, m=-l,l splitting: 0.000 0.000 0.000 0.000 0.000
l=3, charge= 0.002155, m=-l,l splitting: 0.001 0.000 0.001 0.000 0.000 0.000 0.000
l=4, charge= 0.000000, m=-l,l splitting: 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000
Sum of angular contributions for all atomic spheres
l=0, charge = 0.000000 proportion = 0.000000
l=1, charge = 0.985084 proportion = 0.997817
l=2, charge = 0.000000 proportion = 0.000000
l=3, charge = 0.002155 proportion = 0.002183
l=4, charge = 0.000000 proportion = 0.000000
Total over all atoms and l=0 to 4 : 0.987239
Charge in the sphere around each atom
Atom number 1 : charge = 0.98731406
3D wave function was read. Ready for further treatment.
===========================================================
What is your choice ? Type:
0 => exit to k-point / band / spin-pol loop
1 => 3D formatted real and imaginary data
(output the bare 3D data - two column,R,I)
2 => 3D formatted real data
(output the bare 3D data - one column)
3 => 3D formatted imaginary data
(output the bare 3D data - one column)
4 => 3D indexed real and imaginary data
(3D data, preceeded by 3D index)
5 => 3D indexed real data
(bare 3D data, preceeded by 3D index)
6 => 3D indexed imaginary data
(bare 3D data, preceeded by 3D index)
7 => 3D Data Explorer formatted data
(Real file and Imaginary file)
8 => 3D Data Explorer formatted data
(Only the Real file)
9 => 3D Data Explorer formatted data
(Only the Imaginary file)
10 => 3D Data Explorer formatted data and position files
11 => XCrysden formatted data (norm of wf) and position files
12 => NetCDF data and position file
13 => XCrysden/VENUS wavefunction (real part of data)
14 => Gaussian/cube wavefunction module
Your choice is 0
Exit inner loop
Task 0 has been done !
Run interpolation again? (1=default=yes,0=no)
For which k-points? (1 to 3)
=> Your k-point is : 1
For which band ? (1 to 10)
=> Your band number is : 4
=> Your spin polarisation number is : 1
Do you want to analyze a GW wavefunction? (1=yes,0=no)
=> Your choice is : 0
Do you want the atomic analysis for this state :
(kpt,band)= ( 1 4)?
If yes, enter the radius of the atomic spheres, in bohr
If no, enter 0
You entered ratsph= 7.00000000 Bohr
Atomic sphere analysis
wffile : kpgmax, bessargmax, nradint = 1.732051E+00 7.620000E+01 762
Angular analysis (real spherical harmonics)
Atom # 1 is Al, in-sphere charge = 0.987244
l=0, charge= 0.000000, m=-l,l splitting: 0.000
l=1, charge= 0.985088, m=-l,l splitting: 0.000 0.000 0.985
l=2, charge= 0.000000, m=-l,l splitting: 0.000 0.000 0.000 0.000 0.000
l=3, charge= 0.002156, m=-l,l splitting: 0.000 0.000 0.000 0.000 0.001 0.000 0.001
l=4, charge= 0.000000, m=-l,l splitting: 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000
Sum of angular contributions for all atomic spheres
l=0, charge = 0.000000 proportion = 0.000000
l=1, charge = 0.985088 proportion = 0.997816
l=2, charge = 0.000000 proportion = 0.000000
l=3, charge = 0.002156 proportion = 0.002184
l=4, charge = 0.000000 proportion = 0.000000
Total over all atoms and l=0 to 4 : 0.987244
Charge in the sphere around each atom
Atom number 1 : charge = 0.98731899
3D wave function was read. Ready for further treatment.
===========================================================
What is your choice ? Type:
0 => exit to k-point / band / spin-pol loop
1 => 3D formatted real and imaginary data
(output the bare 3D data - two column,R,I)
2 => 3D formatted real data
(output the bare 3D data - one column)
3 => 3D formatted imaginary data
(output the bare 3D data - one column)
4 => 3D indexed real and imaginary data
(3D data, preceeded by 3D index)
5 => 3D indexed real data
(bare 3D data, preceeded by 3D index)
6 => 3D indexed imaginary data
(bare 3D data, preceeded by 3D index)
7 => 3D Data Explorer formatted data
(Real file and Imaginary file)
8 => 3D Data Explorer formatted data
(Only the Real file)
9 => 3D Data Explorer formatted data
(Only the Imaginary file)
10 => 3D Data Explorer formatted data and position files
11 => XCrysden formatted data (norm of wf) and position files
12 => NetCDF data and position file
13 => XCrysden/VENUS wavefunction (real part of data)
14 => Gaussian/cube wavefunction module
Your choice is 0
Exit inner loop
Task 0 has been done !
Run interpolation again? (1=default=yes,0=no)
For which k-points? (1 to 3)
=> Your k-point is : 1
For which band ? (1 to 10)
=> Your band number is : 5
=> Your spin polarisation number is : 1
Do you want to analyze a GW wavefunction? (1=yes,0=no)
=> Your choice is : 0
Do you want the atomic analysis for this state :
(kpt,band)= ( 1 5)?
If yes, enter the radius of the atomic spheres, in bohr
If no, enter 0
You entered ratsph= 7.00000000 Bohr
Atomic sphere analysis
wffile : kpgmax, bessargmax, nradint = 1.732051E+00 7.620000E+01 762
Angular analysis (real spherical harmonics)
Atom # 1 is Al, in-sphere charge = 0.486308
l=0, charge= 0.486306, m=-l,l splitting: 0.486
l=1, charge= 0.000000, m=-l,l splitting: 0.000 0.000 0.000
l=2, charge= 0.000000, m=-l,l splitting: 0.000 0.000 0.000 0.000 0.000
l=3, charge= 0.000000, m=-l,l splitting: 0.000 0.000 0.000 0.000 0.000 0.000 0.000
l=4, charge= 0.000002, m=-l,l splitting: 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000
Sum of angular contributions for all atomic spheres
l=0, charge = 0.486306 proportion = 0.999995
l=1, charge = 0.000000 proportion = 0.000000
l=2, charge = 0.000000 proportion = 0.000000
l=3, charge = 0.000000 proportion = 0.000000
l=4, charge = 0.000002 proportion = 0.000005
Total over all atoms and l=0 to 4 : 0.486308
Charge in the sphere around each atom
Atom number 1 : charge = 0.48632905
3D wave function was read. Ready for further treatment.
===========================================================
What is your choice ? Type:
0 => exit to k-point / band / spin-pol loop
1 => 3D formatted real and imaginary data
(output the bare 3D data - two column,R,I)
2 => 3D formatted real data
(output the bare 3D data - one column)
3 => 3D formatted imaginary data
(output the bare 3D data - one column)
4 => 3D indexed real and imaginary data
(3D data, preceeded by 3D index)
5 => 3D indexed real data
(bare 3D data, preceeded by 3D index)
6 => 3D indexed imaginary data
(bare 3D data, preceeded by 3D index)
7 => 3D Data Explorer formatted data
(Real file and Imaginary file)
8 => 3D Data Explorer formatted data
(Only the Real file)
9 => 3D Data Explorer formatted data
(Only the Imaginary file)
10 => 3D Data Explorer formatted data and position files
11 => XCrysden formatted data (norm of wf) and position files
12 => NetCDF data and position file
13 => XCrysden/VENUS wavefunction (real part of data)
14 => Gaussian/cube wavefunction module
Your choice is 0
Exit inner loop
Task 0 has been done !
Run interpolation again? (1=default=yes,0=no)
For which k-points? (1 to 3)
=> Your k-point is : 1
For which band ? (1 to 10)
=> Your band number is : 6
=> Your spin polarisation number is : 1
Do you want to analyze a GW wavefunction? (1=yes,0=no)
=> Your choice is : 0
Do you want the atomic analysis for this state :
(kpt,band)= ( 1 6)?
If yes, enter the radius of the atomic spheres, in bohr
If no, enter 0
You entered ratsph= 7.00000000 Bohr
Atomic sphere analysis
wffile : kpgmax, bessargmax, nradint = 1.732051E+00 7.620000E+01 762
Angular analysis (real spherical harmonics)
Atom # 1 is Al, in-sphere charge = 0.713503
l=0, charge= 0.000000, m=-l,l splitting: 0.000
l=1, charge= 0.000000, m=-l,l splitting: 0.000 0.000 0.000
l=2, charge= 0.713148, m=-l,l splitting: 0.000 0.000 0.670 0.000 0.043
l=3, charge= 0.000000, m=-l,l splitting: 0.000 0.000 0.000 0.000 0.000 0.000 0.000
l=4, charge= 0.000355, m=-l,l splitting: 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000
Sum of angular contributions for all atomic spheres
l=0, charge = 0.000000 proportion = 0.000000
l=1, charge = 0.000000 proportion = 0.000000
l=2, charge = 0.713148 proportion = 0.999503
l=3, charge = 0.000000 proportion = 0.000000
l=4, charge = 0.000355 proportion = 0.000497
Total over all atoms and l=0 to 4 : 0.713503
Charge in the sphere around each atom
Atom number 1 : charge = 0.71383213
3D wave function was read. Ready for further treatment.
===========================================================
What is your choice ? Type:
0 => exit to k-point / band / spin-pol loop
1 => 3D formatted real and imaginary data
(output the bare 3D data - two column,R,I)
2 => 3D formatted real data
(output the bare 3D data - one column)
3 => 3D formatted imaginary data
(output the bare 3D data - one column)
4 => 3D indexed real and imaginary data
(3D data, preceeded by 3D index)
5 => 3D indexed real data
(bare 3D data, preceeded by 3D index)
6 => 3D indexed imaginary data
(bare 3D data, preceeded by 3D index)
7 => 3D Data Explorer formatted data
(Real file and Imaginary file)
8 => 3D Data Explorer formatted data
(Only the Real file)
9 => 3D Data Explorer formatted data
(Only the Imaginary file)
10 => 3D Data Explorer formatted data and position files
11 => XCrysden formatted data (norm of wf) and position files
12 => NetCDF data and position file
13 => XCrysden/VENUS wavefunction (real part of data)
14 => Gaussian/cube wavefunction module
Your choice is 0
Exit inner loop
Task 0 has been done !
Run interpolation again? (1=default=yes,0=no)
For which k-points? (1 to 3)
=> Your k-point is : 1
For which band ? (1 to 10)
=> Your band number is : 7
=> Your spin polarisation number is : 1
Do you want to analyze a GW wavefunction? (1=yes,0=no)
=> Your choice is : 0
Do you want the atomic analysis for this state :
(kpt,band)= ( 1 7)?
If yes, enter the radius of the atomic spheres, in bohr
If no, enter 0
You entered ratsph= 7.00000000 Bohr
Atomic sphere analysis
wffile : kpgmax, bessargmax, nradint = 1.732051E+00 7.620000E+01 762
Angular analysis (real spherical harmonics)
Atom # 1 is Al, in-sphere charge = 0.713662
l=0, charge= 0.000000, m=-l,l splitting: 0.000
l=1, charge= 0.000000, m=-l,l splitting: 0.000 0.000 0.000
l=2, charge= 0.713308, m=-l,l splitting: 0.000 0.000 0.043 0.000 0.670
l=3, charge= 0.000000, m=-l,l splitting: 0.000 0.000 0.000 0.000 0.000 0.000 0.000
l=4, charge= 0.000354, m=-l,l splitting: 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000
Sum of angular contributions for all atomic spheres
l=0, charge = 0.000000 proportion = 0.000000
l=1, charge = 0.000000 proportion = 0.000000
l=2, charge = 0.713308 proportion = 0.999505
l=3, charge = 0.000000 proportion = 0.000000
l=4, charge = 0.000354 proportion = 0.000495
Total over all atoms and l=0 to 4 : 0.713662
Charge in the sphere around each atom
Atom number 1 : charge = 0.71399158
3D wave function was read. Ready for further treatment.
===========================================================
What is your choice ? Type:
0 => exit to k-point / band / spin-pol loop
1 => 3D formatted real and imaginary data
(output the bare 3D data - two column,R,I)
2 => 3D formatted real data
(output the bare 3D data - one column)
3 => 3D formatted imaginary data
(output the bare 3D data - one column)
4 => 3D indexed real and imaginary data
(3D data, preceeded by 3D index)
5 => 3D indexed real data
(bare 3D data, preceeded by 3D index)
6 => 3D indexed imaginary data
(bare 3D data, preceeded by 3D index)
7 => 3D Data Explorer formatted data
(Real file and Imaginary file)
8 => 3D Data Explorer formatted data
(Only the Real file)
9 => 3D Data Explorer formatted data
(Only the Imaginary file)
10 => 3D Data Explorer formatted data and position files
11 => XCrysden formatted data (norm of wf) and position files
12 => NetCDF data and position file
13 => XCrysden/VENUS wavefunction (real part of data)
14 => Gaussian/cube wavefunction module
Your choice is 0
Exit inner loop
Task 0 has been done !
Run interpolation again? (1=default=yes,0=no)
For which k-points? (1 to 3)
=> Your k-point is : 1
For which band ? (1 to 10)
=> Your band number is : 8
=> Your spin polarisation number is : 1
Do you want to analyze a GW wavefunction? (1=yes,0=no)
=> Your choice is : 0
Do you want the atomic analysis for this state :
(kpt,band)= ( 1 8)?
If yes, enter the radius of the atomic spheres, in bohr
If no, enter 0
You entered ratsph= 7.00000000 Bohr
Atomic sphere analysis
wffile : kpgmax, bessargmax, nradint = 1.732051E+00 7.620000E+01 762
Angular analysis (real spherical harmonics)
Atom # 1 is Al, in-sphere charge = 0.458464
l=0, charge= 0.000000, m=-l,l splitting: 0.000
l=1, charge= 0.307895, m=-l,l splitting: 0.000 0.308 0.000
l=2, charge= 0.000000, m=-l,l splitting: 0.000 0.000 0.000 0.000 0.000
l=3, charge= 0.150569, m=-l,l splitting: 0.000 0.000 0.000 0.151 0.000 0.000 0.000
l=4, charge= 0.000000, m=-l,l splitting: 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000
Sum of angular contributions for all atomic spheres
l=0, charge = 0.000000 proportion = 0.000000
l=1, charge = 0.307895 proportion = 0.671579
l=2, charge = 0.000000 proportion = 0.000000
l=3, charge = 0.150569 proportion = 0.328421
l=4, charge = 0.000000 proportion = 0.000000
Total over all atoms and l=0 to 4 : 0.458464
Charge in the sphere around each atom
Atom number 1 : charge = 0.46210225
3D wave function was read. Ready for further treatment.
===========================================================
What is your choice ? Type:
0 => exit to k-point / band / spin-pol loop
1 => 3D formatted real and imaginary data
(output the bare 3D data - two column,R,I)
2 => 3D formatted real data
(output the bare 3D data - one column)
3 => 3D formatted imaginary data
(output the bare 3D data - one column)
4 => 3D indexed real and imaginary data
(3D data, preceeded by 3D index)
5 => 3D indexed real data
(bare 3D data, preceeded by 3D index)
6 => 3D indexed imaginary data
(bare 3D data, preceeded by 3D index)
7 => 3D Data Explorer formatted data
(Real file and Imaginary file)
8 => 3D Data Explorer formatted data
(Only the Real file)
9 => 3D Data Explorer formatted data
(Only the Imaginary file)
10 => 3D Data Explorer formatted data and position files
11 => XCrysden formatted data (norm of wf) and position files
12 => NetCDF data and position file
13 => XCrysden/VENUS wavefunction (real part of data)
14 => Gaussian/cube wavefunction module
Your choice is 0
Exit inner loop
Task 0 has been done !
Run interpolation again? (1=default=yes,0=no)
For which k-points? (1 to 3)
=> Your k-point is : 1
For which band ? (1 to 10)
=> Your band number is : 9
=> Your spin polarisation number is : 1
Do you want to analyze a GW wavefunction? (1=yes,0=no)
=> Your choice is : 0
Do you want the atomic analysis for this state :
(kpt,band)= ( 1 9)?
If yes, enter the radius of the atomic spheres, in bohr
If no, enter 0
You entered ratsph= 7.00000000 Bohr
Atomic sphere analysis
wffile : kpgmax, bessargmax, nradint = 1.732051E+00 7.620000E+01 762
Angular analysis (real spherical harmonics)
Atom # 1 is Al, in-sphere charge = 0.458452
l=0, charge= 0.000000, m=-l,l splitting: 0.000
l=1, charge= 0.307858, m=-l,l splitting: 0.308 0.000 0.000
l=2, charge= 0.000000, m=-l,l splitting: 0.000 0.000 0.000 0.000 0.000
l=3, charge= 0.150594, m=-l,l splitting: 0.094 0.000 0.056 0.000 0.000 0.000 0.000
l=4, charge= 0.000000, m=-l,l splitting: 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000
Sum of angular contributions for all atomic spheres
l=0, charge = 0.000000 proportion = 0.000000
l=1, charge = 0.307858 proportion = 0.671517
l=2, charge = 0.000000 proportion = 0.000000
l=3, charge = 0.150594 proportion = 0.328483
l=4, charge = 0.000000 proportion = 0.000000
Total over all atoms and l=0 to 4 : 0.458452
Charge in the sphere around each atom
Atom number 1 : charge = 0.46209278
3D wave function was read. Ready for further treatment.
===========================================================
What is your choice ? Type:
0 => exit to k-point / band / spin-pol loop
1 => 3D formatted real and imaginary data
(output the bare 3D data - two column,R,I)
2 => 3D formatted real data
(output the bare 3D data - one column)
3 => 3D formatted imaginary data
(output the bare 3D data - one column)
4 => 3D indexed real and imaginary data
(3D data, preceeded by 3D index)
5 => 3D indexed real data
(bare 3D data, preceeded by 3D index)
6 => 3D indexed imaginary data
(bare 3D data, preceeded by 3D index)
7 => 3D Data Explorer formatted data
(Real file and Imaginary file)
8 => 3D Data Explorer formatted data
(Only the Real file)
9 => 3D Data Explorer formatted data
(Only the Imaginary file)
10 => 3D Data Explorer formatted data and position files
11 => XCrysden formatted data (norm of wf) and position files
12 => NetCDF data and position file
13 => XCrysden/VENUS wavefunction (real part of data)
14 => Gaussian/cube wavefunction module
Your choice is 0
Exit inner loop
Task 0 has been done !
Run interpolation again? (1=default=yes,0=no)
For which k-points? (1 to 3)
=> Your k-point is : 1
For which band ? (1 to 10)
=> Your band number is : 10
=> Your spin polarisation number is : 1
Do you want to analyze a GW wavefunction? (1=yes,0=no)
=> Your choice is : 0
Do you want the atomic analysis for this state :
(kpt,band)= ( 1 10)?
If yes, enter the radius of the atomic spheres, in bohr
If no, enter 0
You entered ratsph= 7.00000000 Bohr
Atomic sphere analysis
wffile : kpgmax, bessargmax, nradint = 1.732051E+00 7.620000E+01 762
Angular analysis (real spherical harmonics)
Atom # 1 is Al, in-sphere charge = 0.458440
l=0, charge= 0.000000, m=-l,l splitting: 0.000
l=1, charge= 0.307822, m=-l,l splitting: 0.000 0.000 0.308
l=2, charge= 0.000000, m=-l,l splitting: 0.000 0.000 0.000 0.000 0.000
l=3, charge= 0.150619, m=-l,l splitting: 0.000 0.000 0.000 0.000 0.056 0.000 0.094
l=4, charge= 0.000000, m=-l,l splitting: 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000
Sum of angular contributions for all atomic spheres
l=0, charge = 0.000000 proportion = 0.000000
l=1, charge = 0.307822 proportion = 0.671454
l=2, charge = 0.000000 proportion = 0.000000
l=3, charge = 0.150619 proportion = 0.328546
l=4, charge = 0.000000 proportion = 0.000000
Total over all atoms and l=0 to 4 : 0.458440
Charge in the sphere around each atom
Atom number 1 : charge = 0.46208348
3D wave function was read. Ready for further treatment.
===========================================================
What is your choice ? Type:
0 => exit to k-point / band / spin-pol loop
1 => 3D formatted real and imaginary data
(output the bare 3D data - two column,R,I)
2 => 3D formatted real data
(output the bare 3D data - one column)
3 => 3D formatted imaginary data
(output the bare 3D data - one column)
4 => 3D indexed real and imaginary data
(3D data, preceeded by 3D index)
5 => 3D indexed real data
(bare 3D data, preceeded by 3D index)
6 => 3D indexed imaginary data
(bare 3D data, preceeded by 3D index)
7 => 3D Data Explorer formatted data
(Real file and Imaginary file)
8 => 3D Data Explorer formatted data
(Only the Real file)
9 => 3D Data Explorer formatted data
(Only the Imaginary file)
10 => 3D Data Explorer formatted data and position files
11 => XCrysden formatted data (norm of wf) and position files
12 => NetCDF data and position file
13 => XCrysden/VENUS wavefunction (real part of data)
14 => Gaussian/cube wavefunction module
Your choice is 0
Exit inner loop
Task 0 has been done !
Run interpolation again? (1=default=yes,0=no)
For which k-points? (1 to 3)
=> Your k-point is : 2
For which band ? (1 to 10)
=> Your band number is : 1
=> Your spin polarisation number is : 1
Do you want to analyze a GW wavefunction? (1=yes,0=no)
=> Your choice is : 0
Do you want the atomic analysis for this state :
(kpt,band)= ( 2 1)?
If yes, enter the radius of the atomic spheres, in bohr
If no, enter 0
You entered ratsph= 7.00000000 Bohr
Atomic sphere analysis
wffile : kpgmax, bessargmax, nradint = 1.732051E+00 7.620000E+01 762
Angular analysis (real spherical harmonics)
Atom # 1 is Al, in-sphere charge = 0.997321
l=0, charge= 0.997055, m=-l,l splitting: 0.997
l=1, charge= 0.000000, m=-l,l splitting: 0.000 0.000 0.000
l=2, charge= 0.000214, m=-l,l splitting: 0.000 0.000 0.000 0.000 0.000
l=3, charge= 0.000000, m=-l,l splitting: 0.000 0.000 0.000 0.000 0.000 0.000 0.000
l=4, charge= 0.000051, m=-l,l splitting: 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000
Sum of angular contributions for all atomic spheres
l=0, charge = 0.997055 proportion = 0.999734
l=1, charge = 0.000000 proportion = 0.000000
l=2, charge = 0.000214 proportion = 0.000215
l=3, charge = 0.000000 proportion = 0.000000
l=4, charge = 0.000051 proportion = 0.000051
Total over all atoms and l=0 to 4 : 0.997321
Charge in the sphere around each atom
Atom number 1 : charge = 0.99743900
3D wave function was read. Ready for further treatment.
===========================================================
What is your choice ? Type:
0 => exit to k-point / band / spin-pol loop
1 => 3D formatted real and imaginary data
(output the bare 3D data - two column,R,I)
2 => 3D formatted real data
(output the bare 3D data - one column)
3 => 3D formatted imaginary data
(output the bare 3D data - one column)
4 => 3D indexed real and imaginary data
(3D data, preceeded by 3D index)
5 => 3D indexed real data
(bare 3D data, preceeded by 3D index)
6 => 3D indexed imaginary data
(bare 3D data, preceeded by 3D index)
7 => 3D Data Explorer formatted data
(Real file and Imaginary file)
8 => 3D Data Explorer formatted data
(Only the Real file)
9 => 3D Data Explorer formatted data
(Only the Imaginary file)
10 => 3D Data Explorer formatted data and position files
11 => XCrysden formatted data (norm of wf) and position files
12 => NetCDF data and position file
13 => XCrysden/VENUS wavefunction (real part of data)
14 => Gaussian/cube wavefunction module
Your choice is 0
Exit inner loop
Task 0 has been done !
Run interpolation again? (1=default=yes,0=no)
For which k-points? (1 to 3)
=> Your k-point is : 3
For which band ? (1 to 10)
=> Your band number is : 1
=> Your spin polarisation number is : 1
Do you want to analyze a GW wavefunction? (1=yes,0=no)
=> Your choice is : 0
Do you want the atomic analysis for this state :
(kpt,band)= ( 3 1)?
If yes, enter the radius of the atomic spheres, in bohr
If no, enter 0
You entered ratsph= 7.00000000 Bohr
Atomic sphere analysis
wffile : kpgmax, bessargmax, nradint = 1.732051E+00 7.620000E+01 762
Angular analysis (real spherical harmonics)
Atom # 1 is Al, in-sphere charge = 0.998950
l=0, charge= 0.998844, m=-l,l splitting: 0.999
l=1, charge= 0.000000, m=-l,l splitting: 0.000 0.000 0.000
l=2, charge= 0.000000, m=-l,l splitting: 0.000 0.000 0.000 0.000 0.000
l=3, charge= 0.000000, m=-l,l splitting: 0.000 0.000 0.000 0.000 0.000 0.000 0.000
l=4, charge= 0.000106, m=-l,l splitting: 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000
Sum of angular contributions for all atomic spheres
l=0, charge = 0.998844 proportion = 0.999894
l=1, charge = 0.000000 proportion = 0.000000
l=2, charge = 0.000000 proportion = 0.000000
l=3, charge = 0.000000 proportion = 0.000000
l=4, charge = 0.000106 proportion = 0.000106
Total over all atoms and l=0 to 4 : 0.998950
Charge in the sphere around each atom
Atom number 1 : charge = 0.99906787
3D wave function was read. Ready for further treatment.
===========================================================
What is your choice ? Type:
0 => exit to k-point / band / spin-pol loop
1 => 3D formatted real and imaginary data
(output the bare 3D data - two column,R,I)
2 => 3D formatted real data
(output the bare 3D data - one column)
3 => 3D formatted imaginary data
(output the bare 3D data - one column)
4 => 3D indexed real and imaginary data
(3D data, preceeded by 3D index)
5 => 3D indexed real data
(bare 3D data, preceeded by 3D index)
6 => 3D indexed imaginary data
(bare 3D data, preceeded by 3D index)
7 => 3D Data Explorer formatted data
(Real file and Imaginary file)
8 => 3D Data Explorer formatted data
(Only the Real file)
9 => 3D Data Explorer formatted data
(Only the Imaginary file)
10 => 3D Data Explorer formatted data and position files
11 => XCrysden formatted data (norm of wf) and position files
12 => NetCDF data and position file
13 => XCrysden/VENUS wavefunction (real part of data)
14 => Gaussian/cube wavefunction module
Your choice is 0
Exit inner loop
Task 0 has been done !
Run interpolation again? (1=default=yes,0=no)
-
- Proc. 0 individual time (sec): cpu= 1.5 wall= 1.5
Thank you for using me
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