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S. Ponce, E. R. Margine, C. Verdi, and F. Giustino,
Comput. Phys. Commun. 209, 116 (2016)
Program EPW v.5.1.0 starts on 25Mar2019 at 11:29:18
This program is part of the open-source Quantum ESPRESSO suite
for quantum simulation of materials; please cite
"P. Giannozzi et al., J. Phys.:Condens. Matter 21 395502 (2009);
"P. Giannozzi et al., J. Phys.:Condens. Matter 29 465901 (2017);
URL http://www.quantum-espresso.org",
in publications or presentations arising from this work. More details at
http://www.quantum-espresso.org/quote
Parallel version (MPI), running on 1 processors
MPI processes distributed on 1 nodes
------------------------------------------------------------------------
RESTART - RESTART - RESTART - RESTART
Restart is done without reading PWSCF save file.
Be aware that some consistency checks are therefore not done.
------------------------------------------------------------------------
--
bravais-lattice index = 0
lattice parameter (a_0) = 0.0000 a.u.
unit-cell volume = 0.0000 (a.u.)^3
number of atoms/cell = 0
number of atomic types = 0
kinetic-energy cut-off = 0.0000 Ry
charge density cut-off = 0.0000 Ry
Exchange-correlation = not set (-1 -1 -1 -1-1-1)
celldm(1)= 0.00000 celldm(2)= 0.00000 celldm(3)= 0.00000
celldm(4)= 0.00000 celldm(5)= 0.00000 celldm(6)= 0.00000
crystal axes: (cart. coord. in units of a_0)
a(1) = ( 0.0000 0.0000 0.0000 )
a(2) = ( 0.0000 0.0000 0.0000 )
a(3) = ( 0.0000 0.0000 0.0000 )
reciprocal axes: (cart. coord. in units 2 pi/a_0)
b(1) = ( 0.0000 0.0000 0.0000 )
b(2) = ( 0.0000 0.0000 0.0000 )
b(3) = ( 0.0000 0.0000 0.0000 )
Atoms inside the unit cell:
Cartesian axes
site n. atom mass positions (a_0 units)
No symmetry!
G cutoff = 0.0000 ( 0 G-vectors) FFT grid: ( 0, 0, 0)
number of k points= 0
cart. coord. in units 2pi/a_0
EPW : 0.00s CPU 0.00s WALL
EPW : 0.00s CPU 0.00s WALL
No wavefunction gauge setting applied
-------------------------------------------------------------------
Using si.ukk from disk
-------------------------------------------------------------------
Using kmap and kgmap from disk
Do not need to read .epb files; read .fmt files
Band disentanglement is used: nbndsub = 8
Use zone-centred Wigner-Seitz cells
Number of WS vectors for electrons 279
Number of WS vectors for phonons 19
Number of WS vectors for electron-phonon 19
Maximum number of cores for efficient parallelization 114
Results may improve by using use_ws == .true.
Reading Hamiltonian, Dynamical matrix and EP vertex in Wann rep from file
Finished reading Wann rep data from file
===================================================================
Memory usage: VmHWM = 12Mb
VmPeak = 272Mb
===================================================================
Using uniform q-mesh: 7 7 7
Size of q point mesh for interpolation: 343
Using uniform MP k-mesh: 7 7 7
Size of k point mesh for interpolation: 40
Max number of k points per pool: 40
Fermi energy coarse grid = 0.000000 eV
Fermi energy is calculated from the fine k-mesh: Ef = 6.339674 eV
Warning: check if difference with Fermi level fine grid makes sense
===================================================================
Applying a scissor shift of 0.70000 eV to the conduction states
ibndmin = 2 ebndmin = 0.190
ibndmax = 7 ebndmax = 0.757
Number of ep-matrix elements per pool : 4320 ~= 33.75 Kb (@ 8 bytes/ DP)
A selecq.fmt file was found but re-created because selecqread == .false.
Number selected, total 50 50
Number selected, total 100 100
Number selected, total 150 150
Number selected, total 200 200
Number selected, total 250 250
Number selected, total 300 300
We only need to compute 343 q-points
Temperature 400.000 K
Valence band maximum = 6.255486 eV
Conduction band minimum = 7.660801 eV
Mobility VB Fermi level 6.861901 eV
Valence band maximum = 6.255486 eV
Conduction band minimum = 7.660801 eV
Mobility CB Fermi level 7.030497 eV
Temperature 500.000 K
Valence band maximum = 6.255486 eV
Conduction band minimum = 7.660801 eV
Mobility VB Fermi level 7.013560 eV
Valence band maximum = 6.255486 eV
Conduction band minimum = 7.660801 eV
Mobility CB Fermi level 6.872904 eV
===================================================================
Scattering rate for IBTE
===================================================================
restart and restart_freq inputs deactivated (restart point at every q-points).
No intermediate mobility will be shown.
Fermi Surface thickness = 4.000000 eV
This is computed with respect to the fine Fermi level 6.339674 eV
Only states between 2.339674 eV and 10.339674 eV will be included
Progression iq (fine) = 50/ 343
Progression iq (fine) = 100/ 343
Progression iq (fine) = 150/ 343
Progression iq (fine) = 200/ 343
Progression iq (fine) = 250/ 343
Progression iq (fine) = 300/ 343
400.000 7.0305 0.100001E+14
500.000 6.8729 0.100000E+14
epmatkqread automatically changed to .true. as all scattering have been computed.
Number of elements per core 1836
Symmetry mapping finished
Average over degenerate eigenstates is performed
=======================================================================
Temp Fermi Elec density Population SR Elec mobility
[K] [eV] [cm^-3] [e per cell] [cm^2/Vs]
=======================================================================
400.000 7.0305 0.10000E+14 0.16156E-26 0.291052E+00 x-axis
0.291048E+00 y-axis
0.291043E+00 z-axis
0.291048E+00 avg
-0.881377E-01 off-diag
500.000 6.8729 0.10000E+14 0.16156E-26 0.226888E+00 x-axis
0.226885E+00 y-axis
0.226882E+00 z-axis
0.226885E+00 avg
-0.584524E-01 off-diag
===================================================================
Start solving iterative Boltzmann Transport Equation
===================================================================
Iteration number: 1
=======================================================================
Temp Fermi Elec density Population SR Elec mobility
[K] [eV] [cm^-3] [e per cell] [cm^2/Vs]
=======================================================================
400.000 7.0305 0.10000E+14 -0.29346E-27 0.247133E+00 x-axis
0.247129E+00 y-axis
0.247125E+00 z-axis
0.247129E+00 avg
-0.749845E-01 off-diag
500.000 6.8729 0.10000E+14 0.40390E-26 0.195015E+00 x-axis
0.195012E+00 y-axis
0.195009E+00 z-axis
0.195012E+00 avg
-0.498150E-01 off-diag
0.247129E+00 Err
Iteration number: 2
=======================================================================
Temp Fermi Elec density Population SR Elec mobility
[K] [eV] [cm^-3] [e per cell] [cm^2/Vs]
=======================================================================
400.000 7.0305 0.10000E+14 0.68158E-27 0.253832E+00 x-axis
0.253828E+00 y-axis
0.253824E+00 z-axis
0.253828E+00 avg
-0.769494E-01 off-diag
500.000 6.8729 0.10000E+14 0.16156E-26 0.199774E+00 x-axis
0.199771E+00 y-axis
0.199768E+00 z-axis
0.199771E+00 avg
-0.511206E-01 off-diag
0.669890E-02 Err
Iteration number: 3
=======================================================================
Temp Fermi Elec density Population SR Elec mobility
[K] [eV] [cm^-3] [e per cell] [cm^2/Vs]
=======================================================================
400.000 7.0305 0.10000E+14 0.13127E-26 0.252806E+00 x-axis
0.252801E+00 y-axis
0.252797E+00 z-axis
0.252801E+00 avg
-0.766570E-01 off-diag
500.000 6.8729 0.10000E+14 0.20195E-26 0.199060E+00 x-axis
0.199057E+00 y-axis
0.199054E+00 z-axis
0.199057E+00 avg
-0.509252E-01 off-diag
0.102669E-02 Err
Iteration number: 4
===================================================================
The iteration reached the maximum but did not converge.
===================================================================
Unfolding on the coarse grid
elphon_wrap : 0.00s CPU 0.00s WALL ( 1 calls)
INITIALIZATION:
Electron-Phonon interpolation
ephwann : 3.68s CPU 4.81s WALL ( 1 calls)
ep-interp : 3.49s CPU 4.62s WALL ( 343 calls)
DynW2B : 0.01s CPU 0.01s WALL ( 343 calls)
HamW2B : 0.29s CPU 0.31s WALL ( 13780 calls)
ephW2Bp : 0.85s CPU 1.81s WALL ( 343 calls)
Total program execution
EPW : 3.68s CPU 4.81s WALL
Please consider citing:
S. Ponce, E. R. Margine, C. Verdi and F. Giustino, Comput. Phys. Commun. 209, 116 (2016)
In addition, if you used anisotropic Eliashberg superconductivity please cite:
E. R. Margine and F. Giustino, Phys. Rev. B 87, 024505 (2013)
if you used transport properties (scattering rates, mobility) please cite:
S. Ponce, E. R. Margine and F. Giustino, Phys. Rev. B 97, 121201 (2018)
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