abinit/tests/v5/Refs/t90.abo

.Version 10.2.4.2 of ANADDB, released Nov 2024.
.(MPI version, prepared for a x86_64_linux_gnu13.2 computer) 

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 ANADDB comes with ABSOLUTELY NO WARRANTY.
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 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
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.Starting date : Tue 19 Nov 2024.
- ( at 18h42 )
  

================================================================================

 -outvars_anaddb: echo values of input variables ----------------------

 Flags :
     ifcflag         1
    elphflag         1
 Miscellaneous information :
       eivec         1
         asr         2
      chneut         0
   symdynmat         0
 Interatomic Force Constants Inputs :
      dipdip         0
      dipqua         1
      quadqu         1
      ifcana         1
      ifcout         0
 Description of grid 1 :
        brav         1
       ngqpt         2         2         2
      nqshft         1
      q1shft
                     0.00000000E+00  0.00000000E+00  0.00000000E+00
 Phonon DOS information :
   dosdeltae  9.11267051E-07
    dossmear  4.55633525E-06
 Description of grid 2 (Fourier interp. or BZ sampling):
      ng2qpt        20        20        20
      ngrids         4
      q2shft         0.00000000E+00  0.00000000E+00  0.00000000E+00
 Elphon calculation will be carried out
   elphsmear    0.100000E-01
    a2fsmear    0.200000E-04
      mustar    0.136000E+00
      nqpath         7
       qpath
                0.000000E+00     0.000000E+00     0.000000E+00
                0.500000E+00     0.500000E+00     0.000000E+00
                0.100000E+01     0.100000E+01     0.100000E+01
                0.500000E+00     0.500000E+00     0.500000E+00
                0.500000E+00     0.500000E+00     0.000000E+00
                0.500000E+00     0.750000E+00     0.250000E+00
                0.500000E+00     0.500000E+00     0.500000E+00
    telphint         1
 Smeared weight integration for elphon
 First list of wavevector (reduced coord.) :
       nph1l         8
       qph1l
                     0.00000000E+00  0.00000000E+00  0.00000000E+00    1.000E+00
                     5.00000000E-01  0.00000000E+00  0.00000000E+00    1.000E+00
                     0.00000000E+00  5.00000000E-01  0.00000000E+00    1.000E+00
                     5.00000000E-01  5.00000000E-01  0.00000000E+00    1.000E+00
                     0.00000000E+00  0.00000000E+00  5.00000000E-01    1.000E+00
                     5.00000000E-01  0.00000000E+00  5.00000000E-01    1.000E+00
                     0.00000000E+00  5.00000000E-01  5.00000000E-01    1.000E+00
                     5.00000000E-01  5.00000000E-01  5.00000000E-01    1.000E+00

================================================================================

 read the DDB information and perform some checks


  ==== Info on the Cryst% object ====
 Real(R)+Recip(G) space primitive vectors, cartesian coordinates (Bohr,Bohr^-1):
 R(1)=  0.0000000  3.7500000  3.7500000  G(1)= -0.1333333  0.1333333  0.1333333
 R(2)=  3.7500000  0.0000000  3.7500000  G(2)=  0.1333333 -0.1333333  0.1333333
 R(3)=  3.7500000  3.7500000  0.0000000  G(3)=  0.1333333  0.1333333 -0.1333333
 Unit cell volume ucvol=  1.0546875E+02 bohr^3
 Angles (23,13,12)=  6.00000000E+01  6.00000000E+01  6.00000000E+01 degrees
 Time-reversal symmetry is present
 Reduced atomic positions [iatom, xred, symbol]:
    1)    0.0000000  0.0000000  0.0000000  Al

 DDB file with 3 blocks has been read.

================================================================================

 Calculation of the interatomic forces 

-begin at tcpu      0.033  and twall      0.033 sec
       Homogeneous q point set in the B.Z.
 Grid q points  :        8
  1)   0.00000000E+00  0.00000000E+00  0.00000000E+00
  2)   5.00000000E-01  0.00000000E+00  0.00000000E+00
  3)   0.00000000E+00  5.00000000E-01  0.00000000E+00
  4)   5.00000000E-01  5.00000000E-01  0.00000000E+00
  5)   0.00000000E+00  0.00000000E+00  5.00000000E-01
  6)   5.00000000E-01  0.00000000E+00  5.00000000E-01
  7)   0.00000000E+00  5.00000000E-01  5.00000000E-01
  8)   5.00000000E-01  5.00000000E-01  5.00000000E-01

 The interatomic forces have been obtained

================================================================================

 Properties based on electron-phonon coupling 

 Found     4 symmetries that leave the perturbation invariant.
 Found     4 symmetries that leave the perturbation invariant.
 Found     4 symmetries that leave the perturbation invariant.
 Found     2 symmetries that leave the perturbation invariant.
 The set of symmetries contains only one element for this perturbation.
 The set of symmetries contains only one element for this perturbation.
 Found     2 symmetries that leave the perturbation invariant.
 Found     2 symmetries that leave the perturbation invariant.
 Found     2 symmetries that leave the perturbation invariant.

 Output of the linewidths for the first point of each segment. Linewidths are given in Hartree.

 Q point =    0.000000E+00    0.000000E+00    0.000000E+00   isppol =    1
 Mode number    Frequency (Ha)  Linewidth (Ha)  Lambda(q,n)
       1        0.000000E+00    3.727509E-10    0.000000E+00
       2        0.000000E+00    3.727509E-10    0.000000E+00
       3        0.000000E+00    3.727509E-10    0.000000E+00

 Q point =    5.000000E-01    5.000000E-01    0.000000E+00   isppol =    1
 Mode number    Frequency (Ha)  Linewidth (Ha)  Lambda(q,n)
       1       -9.501404E-04    9.725237E-06    1.204581E-01
       2       -9.501404E-04    9.725237E-06    1.204581E-01
       3        1.830588E-03    1.182494E-04    3.945743E-01

 Q point =    0.000000E+00    0.000000E+00    0.000000E+00   isppol =    1
 Mode number    Frequency (Ha)  Linewidth (Ha)  Lambda(q,n)
       1        0.000000E+00    3.727509E-10    0.000000E+00
       2        0.000000E+00    3.727509E-10    0.000000E+00
       3        0.000000E+00    3.727509E-10    0.000000E+00

 Q point =    5.000000E-01    5.000000E-01    5.000000E-01   isppol =    1
 Mode number    Frequency (Ha)  Linewidth (Ha)  Lambda(q,n)
       1       -1.129682E-03    5.111316E-22    4.478488E-18
       2       -1.129682E-03    1.660037E-21    1.454509E-17
       3        1.231062E-03    2.510958E-22    1.852641E-18

 Q point =    5.000000E-01    5.000000E-01    0.000000E+00   isppol =    1
 Mode number    Frequency (Ha)  Linewidth (Ha)  Lambda(q,n)
       1       -9.501404E-04    9.725237E-06    1.204581E-01
       2       -9.501404E-04    9.725237E-06    1.204581E-01
       3        1.830588E-03    1.182494E-04    3.945743E-01

 Q point =    5.000000E-01   -2.500000E-01    2.500000E-01   isppol =    1
 Mode number    Frequency (Ha)  Linewidth (Ha)  Lambda(q,n)
       1       -1.070872E-03    5.600905E-06    5.461284E-02
       2        9.900223E-04    5.081929E-05    5.797622E-01
       3        9.900223E-04    5.600907E-06    6.389689E-02

 Q point =    5.000000E-01    5.000000E-01    5.000000E-01   isppol =    1
 Mode number    Frequency (Ha)  Linewidth (Ha)  Lambda(q,n)
       1       -1.129682E-03    5.111316E-22    4.478488E-18
       2       -1.129682E-03    1.660037E-21    1.454509E-17
       3        1.231062E-03    2.510958E-22    1.852641E-18


 Superconductivity : isotropic evaluation of parameters from electron-phonon coupling.

 mka2f: lambda <omega^2> =     2.703980E-07
 mka2f: lambda <omega^3> =     2.972064E-10
 mka2f: lambda <omega^4> =     3.581418E-13
 mka2f: lambda <omega^5> =     4.618597E-16
 mka2f: isotropic lambda =     3.870983E-01
 mka2f: omegalog  =     6.313941E-04 (Ha)     1.993782E+02 (Kelvin)
 mka2f: input mustar =     1.360000E-01
-mka2f: MacMillan Tc =     7.132927E-07 (Ha)     2.252398E-01 (Kelvin)

================================================================================

 Calculation of phonon density of states 

 Average speed of sound partial sums:    -0.6590764220E-03 (at units)
-                                   =          -1.4419 [km/s]

 Debye frequency from partial sums:    -0.5437235852E-03 (Ha)
-                                 =    -0.3577529331E+01 (THz)
-Debye temperature from partial sums:    -0.1716941248E+03 (K)

 Average speed of sound:     0.3008288818E-04 (at units) 
-                      =           0.0658 [km/s]

 Debye frequency from DOS:     0.2481772260E-04 (Ha) 
-                        =     0.1632927703E+00 (THz)
-Debye temperature from DOS:     0.7836807667E+01 (K)


================================================================================

 Treat the first list of vectors 


  Phonon wavevector (reduced coordinates) :  0.00000  0.00000  0.00000
 Phonon energies in Hartree :
   0.000000E+00  0.000000E+00  0.000000E+00
 Phonon frequencies in cm-1    :
-  0.000000E+00  0.000000E+00  0.000000E+00

 Eigendisplacements 
 (will be given, for each mode : in cartesian coordinates
   for each atom the real part of the displacement vector,
   then the imaginary part of the displacement vector - absolute values smaller than 1.0d-7 are set to zero)
  Mode number    1   Energy    0.000000E+00
 Attention : low frequency mode.
   (Could be unstable or acoustic mode)
-  1  0.00000000E+00 -3.26149733E-07  4.50906597E-03
-     0.00000000E+00  0.00000000E+00  0.00000000E+00
  Mode number    2   Energy    0.000000E+00
 Attention : low frequency mode.
   (Could be unstable or acoustic mode)
-  1  0.00000000E+00  4.50906597E-03  3.26149139E-07
-     0.00000000E+00  0.00000000E+00  0.00000000E+00
  Mode number    3   Energy    0.000000E+00
 Attention : low frequency mode.
   (Could be unstable or acoustic mode)
-  1  4.50906598E-03  0.00000000E+00  0.00000000E+00
-     0.00000000E+00  0.00000000E+00  0.00000000E+00

 Analysis of degeneracies and characters (maximum tolerance=1.00E-06 a.u.)
 For each vibration mode, or group of modes if degenerate,
 the characters are given for each symmetry operation (see the list in the log file).
 Symmetry characters of vibration mode #   1
       degenerate with vibration modes #   2 to    3
  3.0 -3.0 -1.0  1.0 -1.0  1.0 -1.0  1.0  1.0 -1.0 -1.0  1.0  1.0 -1.0 -1.0  1.0
  0.0 -0.0 -0.0  0.0 -0.0  0.0  0.0 -0.0  1.0 -1.0 -1.0  1.0 -1.0  1.0  1.0 -1.0
  0.0 -0.0  0.0 -0.0 -0.0  0.0  0.0 -0.0  1.0 -1.0  1.0 -1.0 -1.0  1.0 -1.0  1.0

  Phonon wavevector (reduced coordinates) :  0.50000  0.00000  0.00000
 Phonon energies in Hartree :
  -1.129682E-03 -1.129682E-03  1.231062E-03
 Phonon frequencies in cm-1    :
- -2.479366E+02 -2.479366E+02  2.701868E+02

 Eigendisplacements 
 (will be given, for each mode : in cartesian coordinates
   for each atom the real part of the displacement vector,
   then the imaginary part of the displacement vector - absolute values smaller than 1.0d-7 are set to zero)
  Mode number    1   Energy   -1.129682E-03
 Attention : low frequency mode.
   (Could be unstable or acoustic mode)
-  1  3.33526505E-04 -3.00851753E-03  3.34204404E-03
-     0.00000000E+00  0.00000000E+00  0.00000000E+00
  Mode number    2   Energy   -1.129682E-03
 Attention : low frequency mode.
   (Could be unstable or acoustic mode)
-  1  3.66649843E-03  2.12209164E-03  1.54440679E-03
-     0.00000000E+00  0.00000000E+00  0.00000000E+00
  Mode number    3   Energy    1.231062E-03
;  1  2.60331046E-03 -2.60331046E-03 -2.60331046E-03
;     0.00000000E+00  0.00000000E+00  0.00000000E+00

  Phonon wavevector (reduced coordinates) :  0.00000  0.50000  0.00000
 Phonon energies in Hartree :
  -1.129682E-03 -1.129682E-03  1.231062E-03
 Phonon frequencies in cm-1    :
- -2.479366E+02 -2.479366E+02  2.701868E+02

 Eigendisplacements 
 (will be given, for each mode : in cartesian coordinates
   for each atom the real part of the displacement vector,
   then the imaginary part of the displacement vector - absolute values smaller than 1.0d-7 are set to zero)
  Mode number    1   Energy   -1.129682E-03
 Attention : low frequency mode.
   (Could be unstable or acoustic mode)
-  1  3.33501433E-04 -3.00853204E-03 -3.34203348E-03
-     0.00000000E+00  0.00000000E+00  0.00000000E+00
  Mode number    2   Energy   -1.129682E-03
 Attention : low frequency mode.
   (Could be unstable or acoustic mode)
-  1  3.66650071E-03  2.12207107E-03 -1.54442964E-03
-     0.00000000E+00  0.00000000E+00  0.00000000E+00
  Mode number    3   Energy    1.231062E-03
;  1  2.60331046E-03 -2.60331046E-03  2.60331046E-03
;     0.00000000E+00  0.00000000E+00  0.00000000E+00

  Phonon wavevector (reduced coordinates) :  0.50000  0.50000  0.00000
 Phonon energies in Hartree :
  -9.501404E-04 -9.501404E-04  1.830588E-03
 Phonon frequencies in cm-1    :
- -2.085317E+02 -2.085317E+02  4.017677E+02

 Eigendisplacements 
 (will be given, for each mode : in cartesian coordinates
   for each atom the real part of the displacement vector,
   then the imaginary part of the displacement vector - absolute values smaller than 1.0d-7 are set to zero)
  Mode number    1   Energy   -9.501404E-04
 Attention : low frequency mode.
   (Could be unstable or acoustic mode)
-  1  4.28252509E-07 -4.50906596E-03  0.00000000E+00
-     0.00000000E+00  0.00000000E+00  0.00000000E+00
  Mode number    2   Energy   -9.501404E-04
 Attention : low frequency mode.
   (Could be unstable or acoustic mode)
-  1  4.50906596E-03  4.28252509E-07  0.00000000E+00
-     0.00000000E+00  0.00000000E+00  0.00000000E+00
  Mode number    3   Energy    1.830588E-03
;  1  0.00000000E+00  0.00000000E+00  4.50906598E-03
;     0.00000000E+00  0.00000000E+00  0.00000000E+00

  Phonon wavevector (reduced coordinates) :  0.00000  0.00000  0.50000
 Phonon energies in Hartree :
  -1.129682E-03 -1.129682E-03  1.231062E-03
 Phonon frequencies in cm-1    :
- -2.479366E+02 -2.479366E+02  2.701868E+02

 Eigendisplacements 
 (will be given, for each mode : in cartesian coordinates
   for each atom the real part of the displacement vector,
   then the imaginary part of the displacement vector - absolute values smaller than 1.0d-7 are set to zero)
  Mode number    1   Energy   -1.129682E-03
 Attention : low frequency mode.
   (Could be unstable or acoustic mode)
-  1  3.33489012E-04  3.00853923E-03  3.34202825E-03
-     0.00000000E+00  0.00000000E+00  0.00000000E+00
  Mode number    2   Energy   -1.129682E-03
 Attention : low frequency mode.
   (Could be unstable or acoustic mode)
-  1  3.66650184E-03 -2.12206088E-03  1.54444096E-03
-     0.00000000E+00  0.00000000E+00  0.00000000E+00
  Mode number    3   Energy    1.231062E-03
;  1  2.60331046E-03  2.60331046E-03 -2.60331046E-03
;     0.00000000E+00  0.00000000E+00  0.00000000E+00

  Phonon wavevector (reduced coordinates) :  0.50000  0.00000  0.50000
 Phonon energies in Hartree :
  -9.501404E-04 -9.501404E-04  1.830588E-03
 Phonon frequencies in cm-1    :
- -2.085317E+02 -2.085317E+02  4.017677E+02

 Eigendisplacements 
 (will be given, for each mode : in cartesian coordinates
   for each atom the real part of the displacement vector,
   then the imaginary part of the displacement vector - absolute values smaller than 1.0d-7 are set to zero)
  Mode number    1   Energy   -9.501404E-04
 Attention : low frequency mode.
   (Could be unstable or acoustic mode)
-  1  0.00000000E+00  0.00000000E+00  4.50906598E-03
-     0.00000000E+00  0.00000000E+00  0.00000000E+00
  Mode number    2   Energy   -9.501404E-04
 Attention : low frequency mode.
   (Could be unstable or acoustic mode)
-  1  4.50906598E-03  0.00000000E+00  0.00000000E+00
-     0.00000000E+00  0.00000000E+00  0.00000000E+00
  Mode number    3   Energy    1.830588E-03
;  1  0.00000000E+00  4.50906598E-03  0.00000000E+00
;     0.00000000E+00  0.00000000E+00  0.00000000E+00

  Phonon wavevector (reduced coordinates) :  0.00000  0.50000  0.50000
 Phonon energies in Hartree :
  -9.501404E-04 -9.501404E-04  1.830588E-03
 Phonon frequencies in cm-1    :
- -2.085317E+02 -2.085317E+02  4.017677E+02

 Eigendisplacements 
 (will be given, for each mode : in cartesian coordinates
   for each atom the real part of the displacement vector,
   then the imaginary part of the displacement vector - absolute values smaller than 1.0d-7 are set to zero)
  Mode number    1   Energy   -9.501404E-04
 Attention : low frequency mode.
   (Could be unstable or acoustic mode)
-  1  0.00000000E+00  3.62979744E-05  4.50891988E-03
-     0.00000000E+00  0.00000000E+00  0.00000000E+00
  Mode number    2   Energy   -9.501404E-04
 Attention : low frequency mode.
   (Could be unstable or acoustic mode)
-  1  0.00000000E+00  4.50891988E-03 -3.62979744E-05
-     0.00000000E+00  0.00000000E+00  0.00000000E+00
  Mode number    3   Energy    1.830588E-03
;  1  4.50906598E-03  0.00000000E+00  0.00000000E+00
;     0.00000000E+00  0.00000000E+00  0.00000000E+00

  Phonon wavevector (reduced coordinates) :  0.50000  0.50000  0.50000
 Phonon energies in Hartree :
  -1.129682E-03 -1.129682E-03  1.231062E-03
 Phonon frequencies in cm-1    :
- -2.479366E+02 -2.479366E+02  2.701868E+02

 Eigendisplacements 
 (will be given, for each mode : in cartesian coordinates
   for each atom the real part of the displacement vector,
   then the imaginary part of the displacement vector - absolute values smaller than 1.0d-7 are set to zero)
  Mode number    1   Energy   -1.129682E-03
 Attention : low frequency mode.
   (Could be unstable or acoustic mode)
-  1  3.33762705E-04  3.00838082E-03 -3.34214352E-03
-     0.00000000E+00  0.00000000E+00  0.00000000E+00
  Mode number    2   Energy   -1.129682E-03
 Attention : low frequency mode.
   (Could be unstable or acoustic mode)
-  1  3.66647694E-03 -2.12228545E-03 -1.54419149E-03
-     0.00000000E+00  0.00000000E+00  0.00000000E+00
  Mode number    3   Energy    1.231062E-03
;  1  2.60331046E-03  2.60331046E-03  2.60331046E-03
;     0.00000000E+00  0.00000000E+00  0.00000000E+00
-
- Proc.   0 individual time (sec): cpu=          1.2  wall=          1.3

================================================================================

+Total cpu time      1.236  and wall time      1.280 sec

 anaddb : the run completed succesfully.