band structure of Cobalt monolayer
Posted: Fri Jun 11, 2021 4:22 am
Dear all;,
I tried to make the band structure of monolayer of Cobalt, but what I get is just flat band ,
I attached the input file and the band structure I got ,
I will be grateful for any feedback or remaks
Thank you very much for your comprehnsion
with nice regards
-------------------
# Crystalline Cobalt 13/06/2020
#
# Computation of the band structure.
# First, a SCF density computation, then a non-SCF band structure calculation.
ndtset 2
#Dataset 1 : usual self-consistent calculation
kptopt1 3 # Option for the automatic generation of k points,
# taking into account the full symmetry
#ngkpt1 4 4 1
prtden1 1 # Print the density, for use by dataset 2
toldfe1 1.0d-12 # This value is way too large for most realistic studies of materials
prtdos2 2
#prtdos1 2
ngkpt1 12 12 1
#Dataset 2 : the band structure
iscf2 -2
getden2 -1
kptopt2 -3 # nb of segments Only 2 segment: G->K and K->M to compare with VASP results
nband2 9
ndivk2 100 70 37 # 10, 12 and 17 divisions of the 2 segments, delimited
# by 3 points.
kptbounds 0 0 0 # Gamma
2/3 -1/3 0 # K
1/2 0 0 # M
0 0 0 # Gamma
tolwfr2 1.0d-12
enunit 1 # Will output the eigenenergies in eV
#Definition of the unit cell
#acell 4.737732368 4.737732368 7.690240466
#angdeg 90 90 120
acell 4.737732368 4.737732368 7.690240466
rprim 0.8660254038E+00 5.0000000000E-01 0.0000000000E+00
-0.8660254038E+00 5.0000000000E-01 0.0000000000E+00
0.0000000000E+00 0.0000000000E+00 1.0000000000E+00
pseudos "Co.GGA_PBE-JTH"
#Definition of the atom types
ntypat 1 # There is one types of atoms
znucl 27 # The keyword "znucl" refers to the atomic number of the
# possible type(s) of atom. The pseudopotential(s)
# mentioned in the "files" file must correspond
# to the type(s) of atom. Here, the only type is Silicon.
#Definition of the atoms
natom 6 # There are three atoms
typat 1 1 1 1 1 1 # They are of type 1 Mo,type 2 sulphur .
#xred # This keyword indicate that the location of the atoms
# 1/3 2/3 1/4
# 2/3 1/3 3/4
#or
xcart
0. 0. 0. #Bohr
4.7377 0 0. #Bohr
0 0. 7.96024 #Bohr
4.7377 0 7.96024 #Bohr
2.36885 4.102968 0. #Bohr
2.36885 4.102968 7.96024 #Bohr
#Definition of the planewave basis set
ecut 20.0 # Maximal kinetic energy cut-off, in Hartree
#Definition of the SCF procedure
nstep 50 # Maximal number of SCF cycles
diemac 12.0 # Although this is not mandatory, it is worth to
# precondition the SCF cycle. The model dielectric
# function used as the standard preconditioner
# is described in the "dielng" input variable section.
# Here, we follow the prescription for bulk silicon.
# add to conserve old < 6.7.2 behavior for calculating forces at each SCF step
optforces 1
prtebands 2
prtgeo 2
pawovlp -1
pawecutdg 30
-------------
I tried to make the band structure of monolayer of Cobalt, but what I get is just flat band ,
I attached the input file and the band structure I got ,
I will be grateful for any feedback or remaks
Thank you very much for your comprehnsion
with nice regards
-------------------
# Crystalline Cobalt 13/06/2020
#
# Computation of the band structure.
# First, a SCF density computation, then a non-SCF band structure calculation.
ndtset 2
#Dataset 1 : usual self-consistent calculation
kptopt1 3 # Option for the automatic generation of k points,
# taking into account the full symmetry
#ngkpt1 4 4 1
prtden1 1 # Print the density, for use by dataset 2
toldfe1 1.0d-12 # This value is way too large for most realistic studies of materials
prtdos2 2
#prtdos1 2
ngkpt1 12 12 1
#Dataset 2 : the band structure
iscf2 -2
getden2 -1
kptopt2 -3 # nb of segments Only 2 segment: G->K and K->M to compare with VASP results
nband2 9
ndivk2 100 70 37 # 10, 12 and 17 divisions of the 2 segments, delimited
# by 3 points.
kptbounds 0 0 0 # Gamma
2/3 -1/3 0 # K
1/2 0 0 # M
0 0 0 # Gamma
tolwfr2 1.0d-12
enunit 1 # Will output the eigenenergies in eV
#Definition of the unit cell
#acell 4.737732368 4.737732368 7.690240466
#angdeg 90 90 120
acell 4.737732368 4.737732368 7.690240466
rprim 0.8660254038E+00 5.0000000000E-01 0.0000000000E+00
-0.8660254038E+00 5.0000000000E-01 0.0000000000E+00
0.0000000000E+00 0.0000000000E+00 1.0000000000E+00
pseudos "Co.GGA_PBE-JTH"
#Definition of the atom types
ntypat 1 # There is one types of atoms
znucl 27 # The keyword "znucl" refers to the atomic number of the
# possible type(s) of atom. The pseudopotential(s)
# mentioned in the "files" file must correspond
# to the type(s) of atom. Here, the only type is Silicon.
#Definition of the atoms
natom 6 # There are three atoms
typat 1 1 1 1 1 1 # They are of type 1 Mo,type 2 sulphur .
#xred # This keyword indicate that the location of the atoms
# 1/3 2/3 1/4
# 2/3 1/3 3/4
#or
xcart
0. 0. 0. #Bohr
4.7377 0 0. #Bohr
0 0. 7.96024 #Bohr
4.7377 0 7.96024 #Bohr
2.36885 4.102968 0. #Bohr
2.36885 4.102968 7.96024 #Bohr
#Definition of the planewave basis set
ecut 20.0 # Maximal kinetic energy cut-off, in Hartree
#Definition of the SCF procedure
nstep 50 # Maximal number of SCF cycles
diemac 12.0 # Although this is not mandatory, it is worth to
# precondition the SCF cycle. The model dielectric
# function used as the standard preconditioner
# is described in the "dielng" input variable section.
# Here, we follow the prescription for bulk silicon.
# add to conserve old < 6.7.2 behavior for calculating forces at each SCF step
optforces 1
prtebands 2
prtgeo 2
pawovlp -1
pawecutdg 30
-------------