Li2Mn3NiO8
This material is a complex lithium-based transition metal oxide often investigated for its potential role in energy storage technologies. It is primarily studied as a cathode material for advanced battery systems due to its structural properties that facilitate ion transport.
Key Properties
Cross-validated computational properties for Li2Mn3NiO8, aggregated across 5 databases.
Band GapEnergy needed to move an electron from the valence band to the conduction band. Lower or zero values tend to behave more metallic; larger gaps are more insulating or semiconducting.
Energy Above HullThermodynamic distance from the most stable set of competing phases. 0 eV/atom is on the convex hull; small positive values may still be experimentally accessible.
StabilityA plain-language summary of the best reported energy-above-hull result. It reflects whether the lowest-energy structure is on, near, or far from the stability hull.
StructuresCount of reported calculated crystal structures for this formula, including alternate polymorphs, source databases, and observed space groups.
Reported Structures
Lowest-energy structures reported for Li2Mn3NiO8, ranked by energy above hull.
| Space GroupSymmetry classification of the crystal arrangement. The number is the international space-group index. | Crystal SystemBroad lattice family, such as cubic, tetragonal, monoclinic, or triclinic, derived from unit-cell symmetry. | Band Gap (eV)Electronic gap calculated for this specific reported structure, measured in electronvolts. | E above hull (eV/atom)Thermodynamic distance from the convex hull for this structure, normalized per atom. Lower is generally more stable. | E/atom (eV)Computed total energy normalized per atom. Use energy above hull, not this value alone, when comparing stability. | Density (g/cm³)Mass per relaxed crystal volume, reported in grams per cubic centimeter. |
|---|---|---|---|---|---|
| P4332 (No. 212) | cubic | 1.40 | 0.0000 | -7.427 | 4.27 |
| R-3m (No. 166) | trigonal | 0.55 | 0.0175 | -7.409 | 4.24 |
| P63mc (No. 186) | hexagonal | 1.04 | 0.0472 | -7.380 | 4.35 |
| P21 (No. 4) | monoclinic | 1.63 | 0.0535 | -7.373 | 4.25 |
| P213 (No. 198) | cubic | 1.60 | 0.0665 | -7.360 | 4.26 |
| C2/m (No. 12) | monoclinic | 0.53 | 0.0724 | -7.354 | 4.21 |
| R3m (No. 160) | trigonal | 0.87 | 0.0768 | -7.350 | 4.26 |
| — | — | — | — | — | — |
| — | — | — | — | — | 3.04 |
| P63mc (No. 186) | Hexagonal | — | — | — | 4.73 |
| P63mc (No. 186) | Hexagonal | — | — | — | 4.35 |
| P63mc (No. 186) | — | — | — | — | — |
Applications
Where Li2Mn3NiO8 is used.
Frequently Asked Questions
Common questions about Li2Mn3NiO8, answered from cross-validated data.
What is Li2Mn3NiO8?
This material is a complex lithium-based transition metal oxide often investigated for its potential role in energy storage technologies. It is primarily studied as a cathode material for advanced battery systems due to its structural properties that facilitate ion transport.
What is Li2Mn3NiO8 used for?
What is the band gap of Li2Mn3NiO8?
Is Li2Mn3NiO8 a metal, semiconductor, or insulator?
Is Li2Mn3NiO8 thermodynamically stable?
What is the crystal structure of Li2Mn3NiO8?
What is the density of Li2Mn3NiO8?
How many polymorphs of Li2Mn3NiO8 are known?
What elements does Li2Mn3NiO8 contain?
Where does the data for Li2Mn3NiO8 come from?
Related Compounds
Other Layered Lithium Transition-Metal Oxides in the database.
Data sources & attribution
- materials_project — Data from the Materials Project. Cite: Jain et al., APL Materials 1, 011002 (2013).
- alexandria — Data from alexandria.
- omat24 — Data from OMat24 (Meta FAIR). Cite: Barroso-Luque et al., arXiv 2410.12771 (2024).
- mpaloe — Data from mpaloe.
- jarvis — Data from JARVIS (NIST). Cite: Choudhary et al., npj Comp. Mater. 6, 173 (2020).
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