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Structural formula: Al9Co2

Force-field: Mishin-Al-Co-2013.eam.alloy

Space group : P2_1/c

JARVIS ID: JLMP-1237

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

136.5	88.7	68.9	0.0	-5.9	0.0
88.7	153.4	76.2	-0.0	-4.7	-0.0
68.9	76.2	137.4	0.0	-9.6	0.0
0.0	-0.0	0.0	35.2	-0.0	8.6
-5.9	-4.7	-9.6	-0.0	40.6	-0.0
0.0	-0.0	0.0	8.6	-0.0	28.6

Bv: 99.4 GPa

Gv: 33.8 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
Al		2		-0.107	Download cif file
Al		4		0.226	Download cif file
Al		4		0.372	Download cif file
Al		4		0.091	Download cif file
Al		4		0.257	Download cif file
Co		4		0.954	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 -2)		1.408		Download cif file
(1 0 1)		1.418		Download cif file
(2 0 -3)		1.427		Download cif file
(2 1 2)		1.455		Download cif file
(1 0 3)		1.458		Download cif file
(2 0 3)		1.459		Download cif file
(1 0 0)		1.467		Download cif file
(3 1 3)		1.475		Download cif file
(3 0 2)		1.485		Download cif file
(3 0 -2)		1.498		Download cif file
(3 0 1)		1.498		Download cif file
(2 0 1)		1.5		Download cif file
(2 1 0)		1.504		Download cif file
(3 0 -1)		1.51		Download cif file
(2 1 -2)		1.511		Download cif file
(3 1 -3)		1.512		Download cif file
(3 1 2)		1.514		Download cif file
(2 0 -1)		1.518		Download cif file
(1 0 -1)		1.523		Download cif file
(1 1 -3)		1.526		Download cif file
(1 1 0)		1.533		Download cif file
(1 0 -3)		1.535		Download cif file
(3 2 3)		1.535		Download cif file
(2 2 1)		1.544		Download cif file
(1 1 -1)		1.546		Download cif file
(3 1 1)		1.548		Download cif file
(0 1 3)		1.552		Download cif file
(1 3 0)		1.553		Download cif file
(3 2 -3)		1.561		Download cif file
(1 3 1)		1.566		Download cif file
(3 1 -2)		1.568		Download cif file
(3 3 -2)		1.574		Download cif file
(3 2 2)		1.576		Download cif file
(2 2 3)		1.578		Download cif file
(1 3 -3)		1.581		Download cif file
(3 2 1)		1.582		Download cif file
(2 3 -2)		1.587		Download cif file
(2 2 -3)		1.588		Download cif file
(3 2 -2)		1.588		Download cif file
(3 1 0)		1.591		Download cif file
(2 1 3)		1.594		Download cif file
(0 0 1)		1.595		Download cif file
(2 3 -1)		1.596		Download cif file
(1 1 -2)		1.597		Download cif file
(3 3 2)		1.603		Download cif file
(2 3 3)		1.608		Download cif file
(3 2 0)		1.609		Download cif file
(1 3 2)		1.611		Download cif file
(2 3 -3)		1.615		Download cif file
(3 2 -1)		1.617		Download cif file
(3 1 -1)		1.618		Download cif file
(1 0 2)		1.621		Download cif file
(0 1 2)		1.622		Download cif file
(3 3 1)		1.625		Download cif file
(0 3 1)		1.627		Download cif file
(3 3 -1)		1.628		Download cif file
(1 3 3)		1.629		Download cif file
(1 1 2)		1.63		Download cif file
(2 3 2)		1.632		Download cif file
(0 1 0)		1.634		Download cif file
(2 1 -1)		1.64		Download cif file
(1 2 1)		1.641		Download cif file
(2 3 0)		1.65		Download cif file
(0 2 1)		1.651		Download cif file
(2 3 1)		1.653		Download cif file
(0 2 3)		1.656		Download cif file
(1 3 -2)		1.658		Download cif file
(1 2 0)		1.658		Download cif file
(1 2 -3)		1.661		Download cif file
(0 3 2)		1.664		Download cif file
(2 1 -3)		1.668		Download cif file
(0 1 1)		1.669		Download cif file
(1 2 3)		1.693		Download cif file
(2 1 1)		1.7		Download cif file
(1 3 -1)		1.704		Download cif file
(1 1 3)		1.705		Download cif file
(1 2 -1)		1.706		Download cif file
(2 2 -1)		1.726		Download cif file
(1 2 -2)		1.738		Download cif file
(1 2 2)		1.742		Download cif file
(1 1 1)		1.791		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
-0.0005802909	None
80.7266913404	Bu I
95.5373669035	Ag R
96.4683443728	Bg R
99.4783483329	Au I
110.676239267	Ag R
114.3457574	Bg R
123.667758165	Bu I
125.760537612	Au I
129.09572477	Bu I
130.221072965	Bg R
131.061308337	Au I
139.996993048	Bg R
142.687981935	Ag R
152.377081732	Au I
154.14314279	Ag R
155.549381005	Bu I
157.609708396	Ag R
161.893904808	Au I
165.017325854	Bg R
180.680737841	Bu I
180.733415502	Au I
183.69290505	Au I
185.22031779	Bg R
185.429814557	Ag R
190.243424815	Au I
191.377102924	Bu I
193.997929121	Ag R
195.615468341	Bg R
197.659898986	Bu I
200.81464276	Ag R
204.196880948	Bg R
211.507019304	Ag R
213.011629676	Bu I
215.229913303	Au I
225.052757546	Au I
226.65481613	Bg R
232.619150305	Au I
237.237937202	Ag R
239.469129582	Bu I
246.489194972	Bg R
249.990787877	Bu I
253.947756081	Au I
260.015391194	Bg R
266.091653373	Bu I
267.50198937	Ag R
281.353352325	Au I
283.566027169	Bu I
283.690267799	Bg R
284.003116476	Ag R
294.769727761	Ag R
307.284556495	Au I
308.774167047	Bu I
309.613265194	Ag R
312.067224276	Bg R
323.657461457	Bg R
328.521376719	Bu I
342.957181535	Au I
350.063994957	Au I
350.904815831	Bu I
351.536591036	Bg R
352.679682359	Ag R
376.122447294	Au I
395.044315629	Bu I

All phonon mode at Gamma point (cm-1)
-0.0005802526
-0.0003625313
-0.0003527078
80.7266913404
95.5373669035
96.4683443728
99.4783483329
110.676239267
114.3457574
123.667758165
125.760537612
129.09572477
130.221072965
131.061308337
139.996993048
142.687981935
152.377081732
154.14314279
155.549381005
157.609708396
161.893904808
165.017325854
180.680737841
180.733415502
183.69290505
185.22031779
185.429814557
190.243424815
191.377102924
193.997929121
195.615468341
197.659898986
200.81464276
204.196880948
211.507019304
213.011629676
215.229913303
225.052757546
226.65481613
232.619150305
237.237937202
239.469129582
246.489194972
249.990787877
253.947756081
260.015391194
266.091653373
267.50198937
281.353352325
283.566027169
283.690267799
284.003116476
294.769727761
307.284556495
308.774167047
309.613265194
312.067224276
323.657461457
328.521376719
342.957181535
350.063994957
350.904815831
351.536591036
352.679682359
376.122447294
395.044315629

See also

Links to other databases or papers are provided below

JVASP-11958

mp-16488

Energy above hull from mp (eV): 0.0