Lithium iridate

α-Li₂IrO₃ (scale bar 0.3 mm)^[1]

β-Li₂IrO₃ (scale bar 0.2 mm)^[1]

Crystal structure of α-Li₂IrO₃ with Ir shown in yellow, Li in purple and O in red

Names

Preferred IUPAC name

Lithium iridate

Identifiers

CAS Number

61232-88-0^Y

3D model (JSmol)

Interactive image

InChI

InChI=1S/Ir.2Li.3O/q;2*+1;;2*-1^Y
Key: QPXMDGCGKRSYMN-UHFFFAOYSA-N^Y

SMILES

[Li+].[Li+].[O-][Ir](=O)[O-]

Properties

Chemical formula

Li₂IrO₃

Appearance

Black crystals

Structure

Crystal structure

Monoclinic, C2/m^[2]

Lattice constant

a = 5.1633(2) Å, b = 8.9294(3) Å, c = 5.1219(2) Å

α = 90°, β = 109.759(3)°, γ = 90°

Formula units (Z)

Related compounds

Other anions

Lithium ruthenate, lithium platinate

Other cations

Sodium iridate

Except where otherwise noted, data are given for materials in their standard state (at 25 °C [77 °F], 100 kPa).

N (what is ^YN ?)

Infobox references

Chemical compound

Lithium iridate, Li₂IrO₃, is a chemical compound of lithium, iridium and oxygen. It forms black crystals with three slightly different layered atomic structures, α, β, and sometimes γ. Lithium iridate exhibits metal-like, temperature-independent electrical conductivity, and changes its magnetic ordering from paramagnetic to antiferromagnetic upon cooling to 15 K.

Structure

Li₂IrO₃ typically crystallizes in the α or β phase, and a rare γ phase has been reported. The crystal structure of α-Li₂IrO₃ consists of an alternate stacking of hexagonal Li layers and honeycombs of edge-sharing IrO₆ octahedra with Li in the center. The offset in adjacent layers results in a relatively low (monoclinic) crystal symmetry. Li₂IrO₃ crystals have abundant twinning defects where the ab crystal planes are rotated by 120° around the c axis.^[1]

Synthesis

Li₂IrO₃ crystals can be grown by direct sintering of Ir and Li metals, which both oxidize during heating in ambient atmosphere. The α phase is formed at 750–1050 °C, while heating to higher temperatures results in the β phase. The use of Li metal instead of more traditional lithium carbonate, which is easier to handle and store, results in larger crystals. The γ phase can be obtained by the calcination of lithium carbonate and iridium(IV) oxide, followed by annealing in molten lithium hydroxide at 700–800 °C.^[1]

Properties

Lithium iridate is black in color and has a relatively high, temperature-independent electrical conductivity characteristic of metals.^[2] Its both α and β phases exhibit the Kitaev exchange coupling between magnetic spins originating from Ir⁴⁺ ions. These spins form an antiferromagnetic lattice at temperatures below 15 K (Néel temperature, T_N), while the material is paramagnetic above T_N.^[1]

Potential applications

Lithium iridate is a potential electrode material for the lithium-ion battery.^[2] This application is hindered by the high costs of Ir, as compared to the cheaper Li₂MnO₃ alternative.^[3]

References

Wikimedia Commons has media related to Lithium iridate.

^ ^a ^b ^c ^d ^e ^f ^g Freund, F.; Williams, S. C.; Johnson, R. D.; Coldea, R.; Gegenwart, P.; Jesche, A. (2016). "Single crystal growth from separated educts and its application to lithium transition-metal oxides". Scientific Reports. 6: 35362. arXiv:1604.04551. Bibcode:2016NatSR...635362F. doi:10.1038/srep35362. PMC 5066249. PMID 27748402.
^ ^a ^b ^c O'Malley, Matthew J.; Verweij, Henk; Woodward, Patrick M. (2008). "Structure and properties of ordered Li₂IrO₃ and Li₂PtO₃". Journal of Solid State Chemistry. 181 (8): 1803. Bibcode:2008JSSCh.181.1803O. doi:10.1016/j.jssc.2008.04.005.
^ Yoshio, Masaki; Brodd, Ralph J.; Kozawa, Akiya (17 July 2010). Lithium-Ion Batteries: Science and Technologies. Springer Science & Business Media. p. 10. ISBN 978-0-387-34445-4.