Final Magnetic Moment0.000 μBCalculated total magnetic moment for the unit cell within the magnetic ordering provided (see below). Typically accurate to the second digit. |
Magnetic OrderingNM |
Formation Energy / Atom-3.480 eVCalculated formation energy from the elements normalized to per atom in the unit cell. |
Energy Above Hull / Atom0.089 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. |
Density6.27 g/cm3The calculated bulk crystalline density, typically underestimated due calculated cell volumes overestimated on average by 3% (+/- 6%) |
Decomposes ToHoBO3 |
Band Gap4.547 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 MauguinAma2 [40] |
HallA 2 2a |
Point Groupmm2 |
Crystal Systemorthorhombic |
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%)
substrate material | substrate orientation | film orientation | MCIA† [Å2] |
---|---|---|---|
LaAlO3 (mp-2920) | <0 0 1> | <0 1 0> | 283.1 |
LaAlO3 (mp-2920) | <1 0 0> | <0 0 1> | 137.5 |
LaAlO3 (mp-2920) | <1 0 1> | <0 1 1> | 313.8 |
LaAlO3 (mp-2920) | <1 1 0> | <1 0 1> | 127.9 |
AlN (mp-661) | <0 0 1> | <0 1 1> | 134.5 |
AlN (mp-661) | <1 0 0> | <0 0 1> | 165.0 |
AlN (mp-661) | <1 0 1> | <1 1 0> | 270.8 |
AlN (mp-661) | <1 1 0> | <0 1 1> | 224.1 |
AlN (mp-661) | <1 1 1> | <0 1 1> | 224.1 |
CeO2 (mp-20194) | <1 0 0> | <0 0 1> | 302.5 |
CeO2 (mp-20194) | <1 1 0> | <1 0 1> | 127.9 |
CeO2 (mp-20194) | <1 1 1> | <1 0 1> | 255.8 |
GaAs (mp-2534) | <1 0 0> | <0 0 1> | 165.0 |
GaAs (mp-2534) | <1 1 0> | <0 1 0> | 141.6 |
GaAs (mp-2534) | <1 1 1> | <0 1 0> | 283.1 |
BaF2 (mp-1029) | <1 0 0> | <0 1 0> | 318.5 |
GaN (mp-804) | <0 0 1> | <1 0 1> | 319.7 |
GaN (mp-804) | <1 0 0> | <0 0 1> | 137.5 |
GaN (mp-804) | <1 0 1> | <1 0 1> | 191.8 |
GaN (mp-804) | <1 1 0> | <0 1 1> | 224.1 |
GaN (mp-804) | <1 1 1> | <0 0 1> | 247.5 |
SiO2 (mp-6930) | <0 0 1> | <1 0 0> | 173.2 |
SiO2 (mp-6930) | <1 0 0> | <0 1 1> | 224.1 |
SiO2 (mp-6930) | <1 1 0> | <0 1 0> | 141.6 |
SiO2 (mp-6930) | <1 1 1> | <0 1 0> | 106.2 |
DyScO3 (mp-31120) | <0 0 1> | <0 0 1> | 275.0 |
DyScO3 (mp-31120) | <0 1 0> | <1 1 1> | 219.2 |
DyScO3 (mp-31120) | <0 1 1> | <0 1 1> | 313.8 |
DyScO3 (mp-31120) | <1 0 0> | <1 1 0> | 135.4 |
DyScO3 (mp-31120) | <1 0 1> | <1 0 1> | 319.7 |
DyScO3 (mp-31120) | <1 1 0> | <0 0 1> | 302.5 |
InAs (mp-20305) | <1 0 0> | <0 0 1> | 302.5 |
InAs (mp-20305) | <1 1 0> | <0 1 0> | 106.2 |
ZnSe (mp-1190) | <1 0 0> | <0 0 1> | 165.0 |
ZnSe (mp-1190) | <1 1 0> | <0 1 0> | 141.6 |
ZnSe (mp-1190) | <1 1 1> | <0 1 0> | 283.1 |
KTaO3 (mp-3614) | <1 0 0> | <0 0 1> | 82.5 |
KTaO3 (mp-3614) | <1 1 0> | <0 1 0> | 70.8 |
CdS (mp-672) | <0 0 1> | <0 1 0> | 247.7 |
CdS (mp-672) | <1 0 0> | <0 0 1> | 27.5 |
CdS (mp-672) | <1 0 1> | <0 0 1> | 192.5 |
CdS (mp-672) | <1 1 0> | <1 0 1> | 191.8 |
CdS (mp-672) | <1 1 1> | <0 1 1> | 268.9 |
LiF (mp-1138) | <1 0 0> | <0 0 1> | 82.5 |
LiF (mp-1138) | <1 1 0> | <0 1 0> | 70.8 |
Te2W (mp-22693) | <0 0 1> | <0 0 1> | 247.5 |
Te2W (mp-22693) | <0 1 0> | <1 1 0> | 270.8 |
Te2W (mp-22693) | <0 1 1> | <0 1 0> | 283.1 |
YVO4 (mp-19133) | <1 1 1> | <0 1 0> | 247.7 |
TePb (mp-19717) | <1 0 0> | <1 0 0> | 173.2 |
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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Piezoelectric Tensor eij (C/m2) |
|||||
---|---|---|---|---|---|
0.00000 | 0.00000 | 0.00000 | 0.00000 | 0.60609 | 0.00000 |
0.00000 | 0.00000 | 0.00000 | 0.04132 | 0.00000 | 0.00000 |
0.35332 | -1.11030 | 1.26116 | 0.00000 | 0.00000 | 0.00000 |
Piezoelectric Modulus ‖eij‖max1.71701 C/m2 |
Crystallographic Direction vmax |
---|
0.00000 |
1.00000 |
0.00000 |
Dielectric Tensor εij∞ (electronic contribution) |
||
---|---|---|
3.16 | 0.00 | 0.00 |
0.00 | 3.73 | 0.00 |
0.00 | 0.00 | 3.36 |
Dielectric Tensor εij (total) |
||
---|---|---|
17.34 | 0.00 | 0.00 |
0.00 | 9.61 | 0.00 |
0.00 | 0.00 | 13.98 |
Polycrystalline dielectric constant
εpoly∞
3.42
|
Polycrystalline dielectric constant
εpoly
13.64
|
Refractive Index n1.85 |
Potentially ferroelectric?Unknown |
material | dissimilarity | Ehull | # of elements |
---|---|---|---|
SmBO3 (mp-760477) | 0.1001 | 0.061 | 3 |
TmBO3 (mp-760484) | 0.2933 | 0.030 | 3 |
DyBO3 (mp-753318) | 0.0356 | 0.060 | 3 |
ErBO3 (mp-760405) | 0.0571 | 0.093 | 3 |
YBO3 (mp-760457) | 0.0447 | 0.085 | 3 |
RbHCO2 (mp-24328) | 0.6480 | 0.079 | 4 |
CsHCO2 (mp-542704) | 0.7343 | 0.066 | 4 |
KHCO2 (mp-643989) | 0.6576 | 0.087 | 4 |
Run TypeGGA |
Energy Cutoff520 eV |
# of K-pointsNone |
U Values-- |
PseudopotentialsVASP PAW: Ho_3 B O |
Final Energy/Atom-8.2798 eV |
Corrected Energy-87.0119 eV
-87.0119 eV = -82.7981 eV (uncorrected energy) - 4.2137 eV (MP Anion Correction)
|
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)