Lithium Hydroxide Monohydrate Micron Powder (Trace Metals Basis, LiOH·H₂O), Purity: 99.995% is a high-purity lithium compound widely used in the production of lithium-ion batteries, energy storage systems, and other lithium-based applications. With a purity of 99.995%, this powder is ideal for advanced industrial processes requiring high-performance lithium compounds with minimal trace metal contamination. The monohydrate form of lithium hydroxide ensures stability, ease of handling, and optimal reactivity for battery-grade materials.
1. Key Properties
Ultra-High Purity (99.995%) Ensures extremely low trace metal content, which is critical for high-performance applications such as battery manufacturing where purity directly impacts performance, cycle life, and safety.
Monohydrate Form (LiOH·H₂O) The monohydrate form provides stability during storage and transport, and allows for easier handling compared to anhydrous forms.
Fine Micron Powder The micronized form of lithium hydroxide enhances its reactivity, improving its efficiency in various chemical processes, particularly in the synthesis of lithium-ion battery cathodes.
Low Trace Metal Content The “Trace Metals Basis” specification ensures that impurities, such as iron, copper, or other metals, are minimized to the lowest possible levels, essential for high-precision manufacturing.
Stable Chemical Properties Lithium hydroxide monohydrate is chemically stable, making it suitable for long-term storage without significant degradation or reaction with the atmosphere.
2. Applications
Lithium-Ion Battery Production Lithium hydroxide monohydrate is primarily used in the production of high-capacity cathode materials for lithium-ion batteries, which are essential for electric vehicles (EVs), portable electronics, and energy storage systems.
Energy Storage Systems (ESS) Lithium hydroxide is key in the production of batteries used in large-scale energy storage systems that store energy generated by renewable sources, such as solar and wind.
Lithium Compounds Production Serves as a precursor for producing other lithium compounds such as lithium carbonate and lithium hydroxide, which are critical in various industries, including glass, ceramics, and pharmaceuticals.
Ceramics and Glass Lithium hydroxide is used in the manufacturing of ceramics, specialty glass, and glazes, where it enhances durability and heat resistance.
Pharmaceuticals Lithium compounds derived from lithium hydroxide are used in the treatment of mental health disorders, particularly bipolar disorder.
Industrial Applications Lithium hydroxide is utilized in air purification systems, especially for CO₂ scrubbing, and as a catalyst in various chemical reactions.
3. Advantages
Superior Purity With a purity of 99.995%, the material ensures high performance in critical applications where impurities can negatively affect the end-product, such as in battery production.
Fine Particle Size The micron powder provides excellent reactivity and integration into manufacturing processes, particularly for battery-grade materials.
Low Contamination Risk The ultra-low trace metal content ensures that the material is free from impurities that could otherwise degrade the performance of lithium-ion batteries and other sensitive systems.
Stable Handling The monohydrate form provides ease of handling and storage, reducing the risk of exposure to moisture during the process.
Versatility Lithium hydroxide monohydrate’s use across multiple industries, from batteries to pharmaceuticals, makes it a versatile and valuable material.
4. Recent Trends and Research
Battery Technology Advancements As the demand for high-performance lithium-ion batteries increases, research is focusing on improving lithium hydroxide’s role in the production of high-energy-density cathode materials, such as lithium nickel manganese cobalt (NMC) and lithium iron phosphate (LFP).
Sustainable Battery Manufacturing There is a growing focus on improving the sustainability of lithium production, including methods for recycling lithium from spent batteries and reducing the environmental impact of lithium mining.
Electric Vehicle Growth The expansion of the electric vehicle market is driving increased demand for high-purity lithium hydroxide to produce batteries with longer cycle life and higher energy density.
Energy Storage for Renewable Energy Research is exploring the use of lithium hydroxide in energy storage systems, which are critical for integrating renewable energy sources such as solar and wind into the power grid.
Lithium Extraction and Recycling Research into more sustainable and efficient methods of lithium extraction, as well as recycling of used batteries, will impact the supply of lithium hydroxide for future use in manufacturing.
5. Future Prospects
Electric Vehicles (EVs) The continued growth of the electric vehicle market will significantly increase the demand for high-purity lithium hydroxide, particularly for batteries that offer long range and quick charging capabilities.
Renewable Energy Storage Lithium hydroxide will continue to play a crucial role in developing large-scale energy storage solutions that are vital for stabilizing energy grids powered by renewable sources.
Battery Recycling As the number of lithium-ion batteries in use increases, recycling technologies will focus on recovering lithium from spent batteries, making lithium hydroxide recycling an essential component of a circular economy.
Advanced Battery Chemistries Ongoing research into new and advanced battery chemistries, such as solid-state batteries and lithium-sulfur batteries, will drive further demand for high-purity lithium hydroxide.
Sustainable Lithium Supply The future will likely see more efficient and environmentally friendly lithium extraction and production methods, improving the sustainability of lithium hydroxide manufacturing and reducing its environmental footprint.
With its 99.995% purity, monohydrate form, and micron particle size, Lithium Hydroxide Monohydrate Micron Powder (Trace Metals Basis, LiOH·H₂O) is an essential material for the production of high-performance lithium-ion batteries, energy storage systems, and a wide range of industrial applications. Its exceptional purity and versatility ensure its continued importance in the rapidly evolving fields of energy storage, electric vehicles, and renewable energy technologies.
