material
Li4(FeO2)5
ID:
mp-752950
Final Magnetic Moment23.999 μBCalculated total magnetic moment for the unit cell within the magnetic ordering provided (see below). Typically accurate to the second digit. |
Magnetic OrderingFM |
Formation Energy / Atom-1.944 eVCalculated formation energy from the elements normalized to per atom in the unit cell. |
Energy Above Hull / Atom0.052 eVThe energy of decomposition of this material into the set of most stable materials at this chemical composition, in eV/atom. Stability is tested against all potential chemical combinations that result in the material's composition. For example, a Co2O3 structure would be tested for decomposition against other Co2O3 structures, against Co and O2 mixtures, and against CoO and O2 mixtures. |
Density4.11 g/cm3The calculated bulk crystalline density, typically underestimated due calculated cell volumes overestimated on average by 3% (+/- 6%) |
Decomposes ToLiFeO2 + Fe2O3 + LiO8 |
Band Gap0.337 eVIn general, band gaps computed with common exchange-correlation functionals such as the LDA and GGA are severely underestimated. Typically the disagreement is reported to be ~50% in the literature. Some internal testing by the Materials Project supports these statements; typically, we find that band gaps are underestimated by ~40%. We additionally find that several known insulators are predicted to be metallic. |
Hermann MauguinP1 [1] |
HallP 1 |
Point Group1 |
Crystal Systemtriclinic |
X-Ray Diffraction
-
Select radiation source:
- Cu
- Ag
- Mo
- Fe
Calculated powder diffraction pattern; note that peak spacings may be affected due to inaccuracies in calculated cell volume, which is typically overestimated on average by 3% (+/- 6%)
Substrates
Reference for minimal coincident interface area (MCIA) and elastic energy:substrate orientation:
| substrate material | substrate orientation | film orientation | MCIA† [Å2] |
|---|---|---|---|
| LaAlO3 (mp-2920) | <1 0 0> | <1 1 0> | 208.8 |
| AlN (mp-661) | <0 0 1> | <1 0 -1> | 262.2 |
| AlN (mp-661) | <1 0 0> | <0 0 1> | 78.8 |
| AlN (mp-661) | <1 0 1> | <0 0 1> | 236.3 |
| AlN (mp-661) | <1 1 0> | <0 1 1> | 280.3 |
| AlN (mp-661) | <1 1 1> | <1 0 0> | 309.2 |
| CeO2 (mp-20194) | <1 0 0> | <0 0 1> | 236.3 |
| CeO2 (mp-20194) | <1 1 0> | <1 1 0> | 261.0 |
| CeO2 (mp-20194) | <1 1 1> | <0 1 1> | 160.2 |
| GaAs (mp-2534) | <1 0 0> | <0 1 1> | 160.2 |
| GaAs (mp-2534) | <1 1 0> | <1 -1 -1> | 188.1 |
| GaAs (mp-2534) | <1 1 1> | <1 0 0> | 270.6 |
| GaN (mp-804) | <0 0 1> | <0 0 1> | 183.8 |
| GaN (mp-804) | <1 0 0> | <1 1 -1> | 67.6 |
| GaN (mp-804) | <1 0 1> | <0 0 1> | 78.8 |
| GaN (mp-804) | <1 1 0> | <0 0 1> | 183.8 |
| GaN (mp-804) | <1 1 1> | <0 1 1> | 160.2 |
| SiO2 (mp-6930) | <0 0 1> | <0 0 1> | 131.3 |
| SiO2 (mp-6930) | <1 0 0> | <0 0 1> | 262.6 |
| SiO2 (mp-6930) | <1 0 1> | <1 0 1> | 241.3 |
| SiO2 (mp-6930) | <1 1 0> | <1 -1 1> | 189.0 |
| KCl (mp-23193) | <1 1 1> | <1 0 1> | 281.5 |
| DyScO3 (mp-31120) | <0 0 1> | <0 0 1> | 183.8 |
| DyScO3 (mp-31120) | <0 1 0> | <1 1 0> | 261.0 |
| DyScO3 (mp-31120) | <0 1 1> | <1 -1 -1> | 313.5 |
| DyScO3 (mp-31120) | <1 0 0> | <1 -1 -1> | 188.1 |
| DyScO3 (mp-31120) | <1 1 0> | <0 1 0> | 193.5 |
| DyScO3 (mp-31120) | <1 1 1> | <1 1 1> | 142.7 |
| InAs (mp-20305) | <1 0 0> | <1 1 1> | 333.1 |
| InAs (mp-20305) | <1 1 0> | <0 1 1> | 160.2 |
| InAs (mp-20305) | <1 1 1> | <1 0 0> | 193.3 |
| ZnSe (mp-1190) | <1 0 0> | <0 1 1> | 160.2 |
| ZnSe (mp-1190) | <1 1 0> | <1 -1 -1> | 188.1 |
| ZnSe (mp-1190) | <1 1 1> | <1 0 0> | 270.6 |
| KTaO3 (mp-3614) | <1 0 0> | <0 0 1> | 131.3 |
| KTaO3 (mp-3614) | <1 1 0> | <0 0 1> | 183.8 |
| KTaO3 (mp-3614) | <1 1 1> | <1 0 0> | 193.3 |
| CdS (mp-672) | <0 0 1> | <0 0 1> | 183.8 |
| CdS (mp-672) | <1 0 0> | <1 0 0> | 193.3 |
| CdS (mp-672) | <1 0 1> | <0 1 1> | 200.2 |
| CdS (mp-672) | <1 1 0> | <1 -1 0> | 285.5 |
| CdS (mp-672) | <1 1 1> | <0 1 1> | 200.2 |
| LiF (mp-1138) | <1 0 0> | <0 0 1> | 131.3 |
| LiF (mp-1138) | <1 1 0> | <0 0 1> | 183.8 |
| LiF (mp-1138) | <1 1 1> | <0 1 1> | 120.1 |
| Te2W (mp-22693) | <0 0 1> | <1 0 -1> | 157.3 |
| Te2W (mp-22693) | <0 1 0> | <0 1 0> | 154.8 |
| Te2W (mp-22693) | <0 1 1> | <1 1 1> | 237.9 |
| YVO4 (mp-19133) | <0 0 1> | <1 0 0> | 154.6 |
| YVO4 (mp-19133) | <1 0 0> | <0 1 0> | 193.5 |
Elasticity
A full elastic tensor has not been calculated for this material. Registered users can view statistical-learning-based predictions of this material's bulk and shear moduli.
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Similar Structures
Explanation of dissimilarity measure:
Documentation.
| material | dissimilarity | Ehull | # of elements |
|---|---|---|---|
| Li6V5O12 (mp-765419) | 0.2362 | 0.049 | 3 |
| Li8Mn2O9 (mp-773635) | 0.2064 | 0.066 | 3 |
| Li4V5O10 (mp-762292) | 0.1470 | 0.049 | 3 |
| Li4Zr3O8 (mp-765573) | 0.2476 | 0.045 | 3 |
| Li8V11O22 (mp-768084) | 0.2413 | 0.046 | 3 |
| Li4V3(FeO5)2 (mp-763759) | 0.1995 | 0.078 | 4 |
| Li4Ti2Ni5O12 (mp-762815) | 0.1883 | 0.058 | 4 |
| Li4Ti2Fe3O10 (mp-762758) | 0.2156 | 0.043 | 4 |
| Li4V2Fe3O10 (mp-762757) | 0.1901 | 0.069 | 4 |
| Li3V3CrO8 (mp-769596) | 0.1998 | 0.045 | 4 |
| Fe10O11 (mp-764330) | 0.3082 | 0.056 | 2 |
| Fe9O10 (mp-763441) | 0.3007 | 0.039 | 2 |
| Fe8O9 (mp-705588) | 0.3033 | 0.049 | 2 |
| Fe21O23 (mp-706875) | 0.3218 | 0.052 | 2 |
| Fe10O11 (mp-714908) | 0.2839 | 0.044 | 2 |
| Li6Mn3Cr2Fe3O16 (mp-861553) | 0.3555 | 0.882 | 5 |
Calculation Summary
Structure Optimization
Run TypeGGA+U |
Energy Cutoff520 eV |
# of K-pointsNone |
U ValuesFe: 5.3 eV |
PseudopotentialsVASP PAW: Li_sv Fe_pv O |
Final Energy/Atom-6.0901 eV |
Corrected Energy-136.3989 eV
-136.3989 eV = -115.7110 eV (uncorrected energy) - 13.6650 eV (MP Advanced Correction) - 7.0229 eV (MP Anion Correction)
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Detailed input parameters and outputs for all calculations
Displaying lattice parameters for primitive cell; note that calculated cell volumes are typically overestimated on average by 3% (+/- 6%). Note the primitive cell may appear less symmetric than the conventional cell representation (see "Structure Type" selector below the 3d structure)