JARVIS-FF NIST Disclaimer

Structural formula: FeP4

Force-field: Fe-P.eam.fs

Space group : Cc

JARVIS ID: JLMP-1581

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

119.3 40.0 61.5 -0.0 4.5 0.0
40.0 120.1 61.5 -0.0 0.6 0.0
61.5 61.5 78.3 -0.0 5.2 0.0
-0.0 -0.0 -0.0 39.3 0.0 0.3
4.5 0.6 5.2 0.0 40.2 0.0
0.0 0.0 0.0 0.3 0.0 19.2

Bv: 71.5 GPa

Gv: 30.1 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 0.274 Download cif file
Fe 4 0.264 Download cif file
P 4 -0.62 Download cif file
P 4 -0.613 Download cif file
P 4 -0.647 Download cif file
P 4 -0.638 Download cif file
P 4 -0.776 Download cif file
P 4 -0.461 Download cif file
P 4 -0.689 Download cif file
P 4 -0.524 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
(0 1 0) 0.542 Download cif file
(0 0 1) 0.587 Download cif file
(1 2 0) 0.644 Download cif file
(0 1 1) 0.648 Download cif file
(1 0 1) 0.65 Download cif file
(0 3 2) 0.668 Download cif file
(3 1 3) 0.682 Download cif file
(2 0 3) 0.69 Download cif file
(1 1 1) 0.691 Download cif file
(1 0 3) 0.692 Download cif file
(1 2 2) 0.692 Download cif file
(0 1 3) 0.693 Download cif file
(2 3 0) 0.693 Download cif file
(1 0 2) 0.694 Download cif file
(3 0 2) 0.695 Download cif file
(3 2 3) 0.698 Download cif file
(2 1 2) 0.703 Download cif file
(1 3 3) 0.703 Download cif file
(2 0 1) 0.712 Download cif file
(3 1 1) 0.717 Download cif file
(1 1 2) 0.719 Download cif file
(3 2 2) 0.72 Download cif file
(3 3 1) 0.723 Download cif file
(0 1 2) 0.724 Download cif file
(3 0 1) 0.724 Download cif file
(3 1 2) 0.729 Download cif file
(2 1 3) 0.73 Download cif file
(1 0 0) 0.732 Download cif file
(3 1 0) 0.734 Download cif file
(2 1 1) 0.735 Download cif file
(3 2 1) 0.749 Download cif file
(2 1 0) 0.75 Download cif file
(0 3 1) 0.751 Download cif file
(3 2 0) 0.751 Download cif file
(3 3 2) 0.754 Download cif file
(1 3 0) 0.756 Download cif file
(2 2 1) 0.759 Download cif file
(1 2 3) 0.767 Download cif file
(2 3 3) 0.77 Download cif file
(2 3 1) 0.772 Download cif file
(1 1 3) 0.774 Download cif file
(1 3 2) 0.775 Download cif file
(0 2 3) 0.778 Download cif file
(1 1 0) 0.78 Download cif file
(2 2 3) 0.78 Download cif file
(1 2 1) 0.782 Download cif file
(2 3 2) 0.801 Download cif file
(0 2 1) 0.807 Download cif file
(1 3 1) 0.852 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
-0.0005009263 None
84.4433399721 A I+R
86.3526002002 A I+R
89.8578417226 A I+R
93.7975854255 A I+R
95.0583344242 A I+R
105.10201209 A I+R
105.615504903 A I+R
117.412767109 A I+R
117.536910755 A I+R
127.155432486 A I+R
128.325221643 A I+R
131.274764782 A I+R
134.180977113 A I+R
141.697360742 A I+R
146.737362292 A I+R
147.755433952 A I+R
149.225254326 A I+R
150.984544131 A I+R
161.202994325 A I+R
165.381712066 A I+R
169.922707969 A I+R
170.54663575 A I+R
175.610505375 A I+R
179.657934265 A I+R
184.367653813 A I+R
192.636491024 A I+R
201.349984445 A I+R
203.121714227 A I+R
205.608047264 A I+R
208.312054149 A I+R
208.63727555 A I+R
210.655103743 A I+R
217.721980491 A I+R
221.995668032 A I+R
223.370901697 A I+R
224.652615708 A I+R
226.862589997 A I+R
228.952240351 A I+R
232.498384734 A I+R
238.64040679 A I+R
240.643837728 A I+R
246.100904152 A I+R
252.9120167 A I+R
254.847680497 A I+R
263.000452128 A I+R
267.24297009 A I+R
282.003605476 A I+R
285.062293538 A I+R
290.751123207 A I+R
293.370311093 A I+R
294.030867927 A I+R
298.917570507 A I+R
299.509538503 A I+R
303.789162177 A I+R
313.366313604 A I+R
316.266384562 A I+R
320.961156712 A I+R
All phonon mode at Gamma point (cm-1)
-0.0005009416
-0.0004712172
-0.0003904502
54.5338055155
74.4150304484
74.5439234676
77.7950959844
84.4433399721
86.3526002002
89.421862444
89.8578417226
90.080479242
93.7975854255
95.0583344242
95.7941275024
97.6546665344
101.112427016
102.988968949
105.10201209
105.615504903
116.483099557
117.308438737
117.412767109
117.536910755
120.140675249
126.103658374
127.155432486
128.325221643
131.274764782
131.331311772
134.180977113
134.664386011
135.707417551
141.697360742
143.441576039
146.737362292
147.755433952
148.895535304
149.225254326
149.861254633
150.984544131
151.280969335
152.879230411
159.401804996
160.66303801
161.202994325
164.269554232
165.381712066
168.888591649
169.922707969
170.54663575
170.579764959
173.715480621
175.610505375
178.624610468
179.657934265
180.651962713
182.876173454
184.367653813
191.45934775
192.636491024
201.349984445
203.121714227
204.930026208
205.589957503
205.608047264
208.312054149
208.63727555
208.965500897
210.655103743
213.694578734
216.465590765
217.721980491
221.995668032
223.370901697
224.652615708
226.862589997
228.78572042
228.952240351
229.817769275
232.498384734
233.428376665
236.087628583
238.64040679
240.643837728
246.100904152
249.311049962
252.546422391
252.9120167
254.847680497
256.65854109
257.422572654
263.000452128
263.591009133
265.118069541
267.24297009
270.802281333
275.70402473
277.904404167
278.995940649
280.546196925
282.003605476
283.368226436
285.062293538
289.688066628
290.751123207
293.093854746
293.370311093
294.030867927
298.917570507
299.509538503
303.789162177
304.412296348
309.705292621
313.366313604
314.950348242
316.266384562
319.045838214
319.478368772
320.961156712

See also

Links to other databases or papers are provided below

JVASP-22663

mp-570553

Energy above hull from mp (eV): 0.0