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Structural formula: Fe3C

Force-field: Fe-C_Hepburn_Ackland.eam.fs

Space group : P2_12_12_1

JARVIS ID: JLMP-1559

Download input files

Elastic tensor (GPa)

Elastic tensor for the conventional cell of the system were calculated with LAMMPS in.elastic script at 0 K [Source] . Similar script can be used for temperature dependent elastic constants and will be available here soon. WARNING! Please note that the starting lattice parameters of crystal structures were taken from density functional theory (DFT) and not from experiments. Generic minimization parameters were chosen for LAMMPS run rather than testing them for each individual case such as energy convergence criterion and so on. Hence, there are chances that the calculation gets trapped in a local energy minima. Please read carefully the assumptions taken during calculations in the in.elastic script and use the data at your own risk

1902.7 1020.1 903.4 0.0 -0.0 -0.0
1020.1 833.1 827.4 0.0 -0.0 0.0
903.4 827.4 1284.4 0.0 0.0 -0.0
0.0 0.0 0.0 261.1 -0.0 0.0
-0.0 -0.0 0.0 -0.0 224.9 0.0
-0.0 0.0 -0.0 0.0 0.0 277.7

Bv: 1058.0 GPa

Gv: 237.4 GPa

Vacancy-formation energy (eV)

Vacancy formation energies were calculated by deleting the symmterically distinct atoms in the system [Source]. In the table, vacancy forming element, its multiplicity, and defect-formation energy are given. The reference element cohesive energies were calculated with the most stable structure for the element found on materials project database. Defect structures were constructed with the fully-relaxed bulk system as input. For defect-structures energetics calculations, constant volume ensemble was used. We impose the defect structures to be at least 1.5 nm large in all directions.

Element Mult. Value
Fe 4 -9.819 Download cif file
Fe 4 3.371 Download cif file
Fe 4 -4.54 Download cif file
C 4 2.462 Download cif file

Surface energy (J/m2)

Surface energies were calculated for symmterically distinct crystal surfaces . In the table, (hkl) indices and surface enegies are given. For surface-structure energetics, constant volume ensemble was used. We impose the slab thickness to be at least 2 nm and vaccum size of 2.5 nm. The maximum miller index is taken as 3.

Surface Value
(1 0 3) 2.176 Download cif file
(1 0 2) 2.338 Download cif file
(0 1 0) 2.363 Download cif file
(1 0 0) 2.379 Download cif file
(1 0 1) 2.405 Download cif file
(3 0 2) 2.415 Download cif file
(2 0 3) 2.429 Download cif file
(2 0 1) 2.469 Download cif file
(3 0 1) 2.586 Download cif file
(0 0 1) 2.663 Download cif file
(2 1 0) 3.436 Download cif file
(0 1 1) 3.478 Download cif file
(0 3 1) 3.545 Download cif file
(2 2 1) 3.545 Download cif file
(1 1 0) 3.55 Download cif file
(1 2 1) 3.574 Download cif file
(3 1 2) 3.589 Download cif file
(3 3 1) 3.592 Download cif file
(2 3 3) 3.605 Download cif file
(0 2 3) 3.612 Download cif file
(2 1 2) 3.618 Download cif file
(0 3 2) 3.62 Download cif file
(3 2 3) 3.622 Download cif file
(1 1 1) 3.625 Download cif file
(2 3 1) 3.631 Download cif file
(2 3 0) 3.633 Download cif file
(0 1 2) 3.651 Download cif file
(1 3 2) 3.668 Download cif file
(3 2 2) 3.681 Download cif file
(2 1 1) 3.689 Download cif file
(1 2 0) 3.69 Download cif file
(1 2 2) 3.702 Download cif file
(2 2 3) 3.702 Download cif file
(1 3 1) 3.712 Download cif file
(1 1 3) 3.713 Download cif file
(3 1 3) 3.731 Download cif file
(3 2 1) 3.734 Download cif file
(3 1 1) 3.737 Download cif file
(1 3 0) 3.746 Download cif file
(3 1 0) 3.757 Download cif file
(2 1 3) 3.763 Download cif file
(1 3 3) 3.772 Download cif file
(3 3 2) 3.835 Download cif file
(3 2 0) 3.84 Download cif file
(1 2 3) 3.85 Download cif file
(1 1 2) 3.861 Download cif file
(0 1 3) 3.898 Download cif file
(2 3 2) 3.907 Download cif file
(0 2 1) 4.017 Download cif file

Phonon

Phonons were obtained by making an interface of JARVIS-FF with Phonopy package at 0 K [Source] . For deformed-structures, constant volume ensemble was used. The deofrmed structures were taken of at least 1.5 nm size in all directions. The band-indices for phonon bandstructure was obtained with Pymatgen. The phonon representation were obtained with phonopy. "I" and "R" denotes infrared and Raman active modes respectively

Visualize Phonons here
Phonon mode (cm-1) Representation
-0.1614404928 B3 I+R
-0.1313605983 B1 I+R
-0.1239902151 B2 I+R
95.4292548009 B2 I+R
127.496719573 B1 I+R
142.477739187 A R
178.16102514 A R
181.964560949 B1 I+R
186.47908729 B3 I+R
203.724843401 A R
207.56037852 B3 I+R
259.486270252 B2 I+R
268.451906735 A R
291.867237171 B1 I+R
302.468975252 B3 I+R
313.1566942 B2 I+R
321.918306881 B3 I+R
350.170123253 B1 I+R
351.647565583 B2 I+R
354.927705226 A R
360.981979102 B3 I+R
387.24491921 B1 I+R
434.524747274 A R
444.904723687 B2 I+R
833.818374761 B3 I+R
834.009611313 B2 I+R
844.519271537 B1 I+R
859.64067656 A R
1033.21946913 B1 I+R
1037.32505416 A R
1635.65255546 B2 I+R
1639.3955443 B3 I+R
1718.76051838 B2 I+R
1725.21592172 B3 I+R
1725.23875535 B1 I+R
1725.99675203 A R
3997.85054157 B3 I+R
4025.03275269 B2 I+R
4049.81176096 A R
4102.70429668 B1 I+R
4330.06179836 B2 I+R
4375.60534658 B1 I+R
4404.41785061 B3 I+R
4442.26689201 A R
4553.86121824 B3 I+R
4594.6092308 B2 I+R
4629.69687061 A R
4662.03526407 B1 I+R
All phonon mode at Gamma point (cm-1)
-0.1614404973
-0.1313605983
-0.1239902151
95.4292548009
127.496719573
142.477739187
178.16102514
181.964560949
186.47908729
203.724843401
207.56037852
259.486270252
268.451906735
291.867237171
302.468975252
313.1566942
321.918306881
350.170123253
351.647565583
354.927705226
360.981979102
387.24491921
434.524747274
444.904723687
833.818374761
834.009611313
844.519271538
859.64067656
1033.21946913
1037.32505416
1635.65255546
1639.3955443
1718.76051838
1725.21592172
1725.23875535
1725.99675203
3997.85054157
4025.03275269
4049.81176096
4102.70429668
4330.06179836
4375.60534658
4404.41785061
4442.26689201
4553.86121824
4594.6092308
4629.69687061
4662.03526407

See also

Links to other databases or papers are provided below

None

mp-613523

Energy above hull from mp (eV): 0.129103744062