• 1. Bond distances are not always what they appear to be: discovery and un-discovery of the longest Cr(v)N triple bond
  Yu-Fei Song,John F. Berry,Thomas Weyhermüller,Eckhard Bill Dalton Trans. 2008 1864
• 2. Influence of deuteration on lithium acetate dihydrate studied by inelastic X-ray scattering, density functional theory, thermal expansion, elastic and thermodynamic measurements
  B. Winkler,E. Haussühl,J. D. Bauer,F. Schr?der,K. Refson,V. Milman,B. Hennion,A. Bossak,M. Krisch Dalton Trans. 2011 40 1737
• 3. Mechanistic insights into the acetate-accelerated synthesis of crystalline ceria nanoparticles
  Tamra J. Fisher,Deepa Choudhry,Kaitlynn Derr,Soodabeh Azadehranjbar,Dan Stasko,Chin Li Cheung RSC Adv. 2020 10 20515
• 4. A rapid method to assess reactive oxygen species in yeast using H2DCF-DA
  Joel James,Nikita Fiji,Debasish Roy,Daniel Andrew MG,Mohamed Sham Shihabudeen,Debarati Chattopadhyay,Kavitha Thirumurugan Anal. Methods 2015 7 8572
• 5. Physicochemical and electrochemical characterization of salt-in-water and water-in-salt potassium and lithium acetate electrolytes
  Mona Amiri,Daniel Bélanger J. Mater. Chem. A 2021 9 24012

• Solvents and Organic Chemicals Organic Compounds Organic acids and derivatives Carboxylic acids and derivatives Carboxylic acid salts
• Solvents and Organic Chemicals Organic Compounds Organic acids and derivatives Carboxylic acids and derivatives Carboxylic acid derivatives Carboxylic acid salts
• Catalysts and Inorganic Chemicals Inorganic Compounds Salt
• Catalysts and Inorganic Chemicals Inorganic Compounds

Professional Introduction to Lithium Acetate (CAS No. 546-89-4)

Lithium acetate, a compound with the chemical formula C?H?LiO?, is widely recognized for its significant applications in the fields of pharmaceuticals, research, and industrial processes. The compound is identified by its CAS number 546-89-4, which serves as a unique identifier in chemical databases and literature. This introduction delves into the properties, applications, and recent advancements associated with lithium acetate, emphasizing its role in modern scientific and industrial contexts.

The versatility of lithium acetate stems from its chemical structure, which combines the stability of acetate ions with the unique properties of lithium. As a salt, it exhibits high solubility in water and organic solvents, making it an ideal medium for various chemical reactions and formulations. In pharmaceutical research, lithium acetate has been explored for its potential in drug delivery systems and as an intermediate in the synthesis of more complex molecules.

Recent studies have highlighted the role of lithium acetate in cellular biology and neuroscience. Its ability to mimic lithium's effects on neurotransmitter systems has made it a subject of interest in the development of treatments for neurological disorders. For instance, research has demonstrated that lithium acetate can modulate the activity of certain ion channels and enzymes involved in mood regulation and cognitive function. These findings have opened new avenues for therapeutic interventions targeting conditions such as depression and neurodegenerative diseases.

In addition to its pharmaceutical applications, lithium acetate plays a crucial role in industrial processes. It is commonly used as a precursor in the production of lithium-based catalysts, which are essential in various organic synthesis reactions. The compound's ability to facilitate cross-coupling reactions, such as Suzuki-Miyaura coupling, has made it indispensable in the pharmaceutical and fine chemical industries. Moreover, lithium acetate is utilized in the preparation of lithium-ion batteries, where it contributes to the efficient functioning of electrode materials.

The environmental impact of lithium acetate has also been a focus of recent research. Studies have investigated its biodegradability and toxicity profile, ensuring that its use does not pose significant risks to ecosystems. Efforts have been made to develop sustainable methods for synthesizing lithium acetate, reducing reliance on energy-intensive processes. These advancements align with global initiatives aimed at promoting green chemistry and minimizing environmental footprints.

Another emerging application of lithium acetate is in agricultural science. It has been explored as a plant growth regulator due to its ability to enhance nutrient uptake and stress resistance in crops. Experiments have shown that when applied appropriately, lithium acetate can improve yield and quality without adverse effects on plant health or soil composition. This potential makes it a promising candidate for sustainable agricultural practices.

The future prospects of lithium acetate are vast, with ongoing research uncovering new applications across multiple disciplines. Innovations in nanotechnology have led to the development of nanostructured forms of lithium acetate, which exhibit enhanced reactivity and efficiency in various processes. Furthermore, collaborations between academia and industry are driving the exploration of novel uses for this compound, ensuring its relevance in cutting-edge scientific advancements.

In conclusion, lithium acetate (CAS No. 546-89-4) is a multifaceted compound with significant implications in pharmaceuticals, industry, agriculture, and environmental science. Its unique properties make it indispensable in numerous applications, while ongoing research continues to expand its potential uses. As scientific understanding evolves, so too will the applications and benefits derived from this versatile compound.

• 2845-03-6(Acetic-1-14C acid(6CI,7CI,8CI,9CI))
• 6108-17-4(Lithium acetate dihydrate)
• 17217-83-3(Acetic-18O2 acid(6CI,8CI,9CI))
• 147416-04-4(ferric vibriobactin receptor)
• 107745-70-0(Acetic Acid-13C2, D3)
• 119510-26-8(VoSol (9CI))
• 1112-02-3(Acetic-2,2,2-d3 Acid)
• 3094-87-9(Iron(II) acetate)
• 1186-52-3(Acetic Acid-d4)
• 1834-30-6(Acetic acid, iron(3+)salt (3:1))