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Sigma-Aldrich

Lithium hydroxide monohydrate

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battery grade, ≥99.9% trace metals basis

Synonym(s):

Lithine hydrate, Lithium hydroxide hydrate

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About This Item

Linear Formula:
LiOH · H2O
CAS Number:
Molecular Weight:
41.96
MDL number:
UNSPSC Code:
12352305
NACRES:
NA.21

Quality Level

grade

battery grade

Assay

≥99.9% trace metals basis

form

powder

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sustainability

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impurities

≤1000 ppm (trace metals analysis)

mp

423 °C

solubility

H2O: soluble ((lit.))
ethanol: slightly soluble ((lit.))
methanol: soluble ((lit.))

anion traces

chloride (Cl-): ≤50 ppm
sulfate (SO42-): ≤50 ppm

application(s)

battery manufacturing

greener alternative category

SMILES string

[Li+].O.[OH-]

InChI

1S/Li.2H2O/h;2*1H2/q+1;;/p-1

InChI key

GLXDVVHUTZTUQK-UHFFFAOYSA-M

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General description

Lithium hydroxide monohydrate is a white-to-colorless, crystalline salt. The monohydrate is hygroscopic. It is soluble in water and generates heat when dissolving. It is also soluble in methanol, somewhat soluble in ethanol, but only sparingly soluble in isopropanol.
Lithium hydroxide is produced in several ways. Most commonly, lithium carbonate is reacted with calcium hydroxide in a metathesis reaction. This directly yields lithium hydroxide hydrate, which is separated from the insoluble calcium carbonate byproduct and purified. Alternatively, when the source of lithium is spodumene ore, the ore can be converted to lithium hydroxide without first forming the carbonate. In the process, the lithium ore is treated with high-temperatures and sulfuric acid to form lithium sulfate; then the lithium sulfate is reacted with sodium hydroxide to form lithium hydroxide hydrate, which is purified.
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Application

The primary application of battery-grade lithium hydroxide is in the synthesis and manufacturing of cathode materials for lithium-ion batteries. In particular, lithium hydroxide is the reagent of choice for making nickel-rich cathodes like nickel-manganese-cobalt oxide (NMC) and nickel-cobalt-aluminum oxide (NCA). For these materials, the nickel-rich precursors must be fired in oxygen at relatively low temperatures (~500 °C) in order to promote higher oxidation states of nickel while suppressing cation mixing. Lithium hydroxide, which melts at 462 °C, is preferred because it melts at these temperatures, yielding more complete reactions and superior crystallinity, than reactions using lithium carbonate. Lithium carbonate, which melts at 723 °C, is still a solid at these temperatures.
Our battery grade lithium hydroxide monohydrate is well-suited for synthesis of nickel-rich metal oxides, like lithium nickel-manganese-aluminum oxide (NMA) and complex quaternary transition metal oxides like Zr-doped or Ti-doped nickel-manganese oxide.
Our lithium hydroxide monohydrate can also be used to synthesize lithium iron phosphates like LiFePO4 or lithium manganese oxides like Li2Mn2O4.

Pictograms

CorrosionExclamation mark

Signal Word

Danger

Hazard Statements

Hazard Classifications

Acute Tox. 4 Oral - Eye Dam. 1 - Skin Corr. 1B

Storage Class Code

8A - Combustible corrosive hazardous materials

WGK

WGK 1

Flash Point(F)

Not applicable

Flash Point(C)

Not applicable


Certificates of Analysis (COA)

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Wangda Li et al.
Advanced materials (Deerfield Beach, Fla.), 32(33), e2002718-e2002718 (2020-07-07)
High-nickel LiNi1- x - y Mnx Coy O2 (NMC) and LiNi1- x - y Cox Aly O2 (NCA) are the cathode materials of choice for next-generation high-energy lithium-ion batteries. Both NMC and NCA contain cobalt, an expensive and scarce metal
Chemical and Magnetic Characterization of Spinel Materials in the LiMn2O4?Li2Mn4O9?Li4Mn5O12 System.
Masquelie C, et al.
Journal of Solid State Chemistry, 123, 255-266 (1996)
Electrochemical and Structural Properties of xLi2M`O3?(1?x)LiMn0.5Ni0.5O2 Electrodes for Lithium Batteries (M` = Ti, Mn, Zr; 0 ? x ? 0.3).
Chemistry of Materials, 16, 1996-2006 (2004)
Designing principle for Ni-rich cathode materials with high energy density for practical applications.
Xia Y, et al.
Nano Energy, 49, 434-452 (2018)
Li Wang et al.
Nano letters, 12(11), 5632-5636 (2012-10-19)
We report the crystal orientation tuning of LiFePO(4) nanoplates for high rate lithium battery cathode materials. Olivine LiFePO(4) nanoplates can be easily prepared by glycol-based solvothermal process, and the largest crystallographic facet of the LiFePO(4) nanoplates, as well as so-caused

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