Lithium Hydroxide, Monohydrate Micron Powder (Battery Grade, LiOH·H₂O), Purity: ≥ 99.0% is a high-purity chemical compound essential for the production of lithium-ion batteries and other energy storage applications. With a purity of ≥ 99.0%, this powder is ideal for use in battery manufacturing, particularly in the production of cathodes for lithium batteries, as well as in other industrial applications requiring high-purity lithium compounds.
1. Key Properties
High Purity (≥ 99.0%) Ensures minimal contaminants, crucial for high-performance applications, particularly in the production of lithium-ion batteries and energy storage systems.
Monohydrate Form The monohydrate form of lithium hydroxide provides stability, ease of handling, and optimal reactivity for manufacturing processes.
High Reactivity Exhibits excellent chemical reactivity, which is essential for producing lithium-ion batteries and other lithium-based products.
Particle Size Fine micron powder ensures efficient dispersion and integration into battery cathodes and other applications requiring high purity.
Moisture Control The monohydrate form helps in controlling moisture content during the manufacturing process, ensuring optimal performance and material integrity.
2. Applications
Battery Manufacturing Used in the production of cathode materials for lithium-ion batteries, especially for electric vehicles (EVs) and energy storage systems (ESS), where high purity is critical for performance and longevity.
Lithium Compounds Production Essential for producing lithium salts used in various industrial processes, including lithium carbonate, lithium metal, and lithium-based catalysts.
Ceramics and Glass Employed in the manufacturing of specialized ceramics and glass, particularly those used in high-temperature environments.
Pharmaceuticals and Medical Applications Used in the production of certain pharmaceutical products that require lithium as an active ingredient.
Water Treatment In some cases, lithium hydroxide is used for water treatment applications, particularly in removing impurities or adjusting the pH in certain industrial processes.
Chemical Synthesis Serves as a key reagent in various chemical processes requiring lithium compounds for reactions.
3. Advantages
High Purity The high purity ensures excellent performance in critical applications, particularly in energy storage systems where lithium-ion battery efficiency is paramount.
Efficient Reactivity The micron-sized particles improve the reactivity and compatibility with other compounds in battery manufacturing and other applications.
Optimal Performance in Batteries Essential for the production of high-performance lithium batteries with long life cycles, especially for electric vehicles and renewable energy storage.
Stable Handling The monohydrate form offers enhanced stability and easier handling compared to other lithium compounds, ensuring minimal loss during storage and transportation.
Versatile Application Can be used in a wide range of industries, from energy storage to ceramics, enhancing its commercial value across different sectors.
4. Recent Trends and Research
Electric Vehicle (EV) Growth As the demand for electric vehicles increases, the need for high-quality lithium hydroxide for battery production continues to grow, driving research into more efficient and sustainable production methods.
Energy Storage Systems (ESS) Lithium hydroxide plays a key role in the development of large-scale energy storage systems that are essential for stabilizing renewable energy grids.
Battery Recycling Advances in battery recycling technologies focus on recovering lithium from spent batteries, driving the need for higher-quality and more easily processed lithium compounds.
Alternative Battery Chemistries Research is exploring the use of lithium hydroxide in developing new battery chemistries that improve energy density, charging times, and overall battery performance.
Sustainability There is ongoing research into reducing the environmental impact of lithium extraction and production, promoting greener practices in battery-grade lithium hydroxide manufacturing.
5. Future Prospects
Electric Vehicles As the global shift toward electric vehicles continues, the demand for lithium hydroxide will grow significantly, especially for high-capacity, long-lifespan lithium-ion batteries.
Energy Storage and Renewable Integration Lithium hydroxide’s use in energy storage systems will become increasingly important for enabling the widespread adoption of renewable energy sources.
Battery Recycling Advancements Ongoing research into efficient battery recycling will drive innovations in reusing lithium hydroxide from old batteries, reducing the need for primary extraction and promoting sustainability.
Next-Generation Batteries Lithium hydroxide will continue to be a key component in the development of next-generation battery technologies that offer higher energy densities and faster charging times.
Environmental Sustainability The move toward more sustainable lithium production methods, such as improving mining practices and recycling technologies, will enhance the role of lithium hydroxide in the green economy.
With its ≥ 99.0% purity, monohydrate form, and micron particle size, Lithium Hydroxide, Monohydrate Micron Powder (Battery Grade, LiOH·H₂O) is an essential material for the production of high-performance lithium-ion batteries, contributing significantly to the growing electric vehicle and renewable energy markets. Its versatile applications in both energy storage and industrial processes make it a cornerstone in modern materials science and technology.
