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• 2. Evaluation and optimization of the influence of silver cluster ions on the MALDI-TOF-MS analysis of polystyrene nanoplastic polymers
  Théogène Habumugisha,Zixing Zhang,Jean Claude Ndayishimiye,Fran?ois Nkinahamira,Alexis Kayiranga,Eric Cyubahiro,Abdul Rehman,Changzhou Yan,Xian Zhang Anal. Methods 2022 14 763
• 3. 177. The reactions of metallic salts of acidss with halogens. Part II. The interaction of silver trifluoroacetate or silver perchlorate and halogens in various solvents
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• 4. Preparation of acyltetronic acids using t-butyl acetothioacetate: total synthesis of the fungal metabolites carolic, carlosic, and carlic acids
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• 5. Phenanthrene–silver ion complexes in trifluoroacetic acid, and their influence on the rates of detritiation of [9-3H]phenanthrene in the presence of silver trifluoroacetate
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• Solvents and Organic Chemicals Organic Compounds Organic acids and derivatives Carboxylic acids and derivatives Alpha-halocarboxylic acids
• Solvents and Organic Chemicals Organic Compounds Organic acids and derivatives Carboxylic acids and derivatives Alpha-halocarboxylic acids and derivatives Alpha-halocarboxylic acids
• Catalysts and Inorganic Chemicals Inorganic Compounds Salt
• Catalysts and Inorganic Chemicals Inorganic Compounds

Silver Trifluoroacetate: A Comprehensive Overview

Silver trifluoroacetate, also known as silver triflate, is a versatile compound with the CAS number 2966-50-9. This compound, represented by the chemical formula AgCF3COO, has garnered significant attention in various fields due to its unique properties and wide-ranging applications. In this article, we will delve into the characteristics, uses, and recent advancements associated with silver trifluoroacetate.

The structure of silver trifluoroacetate consists of a silver ion (Ag+) and a trifluoroacetate ion (CF3COO-). The trifluoroacetate group is highly electronegative due to the presence of three fluorine atoms, which imparts strong electron-withdrawing properties to the compound. This characteristic makes silver triflate an excellent Lewis acid, capable of coordinating with various substrates in chemical reactions.

Silver trifluoroacetate is widely used as a catalyst in organic synthesis. Its ability to activate carbonyl groups makes it particularly effective in promoting reactions such as acylation, esterification, and alkylation. Recent studies have highlighted its role in asymmetric catalysis, where it facilitates the formation of chiral centers with high enantioselectivity. For instance, researchers have employed silver triflate in the synthesis of bioactive molecules, demonstrating its potential in drug discovery and development.

In addition to its catalytic applications, silver triflate has found utility in materials science. It serves as a precursor for the synthesis of silver nanoparticles, which are widely used in electronics, optics, and biomedical applications. The controlled reduction of silver triflate under specific conditions allows for the production of nanoparticles with tailored sizes and shapes, enhancing their performance in various technologies.

The synthesis of silver trifluoroacetate typically involves the reaction of silver oxide with trifluoroacetic acid (TFA). This process yields a high-purity product that is stable under most conditions. However, care must be taken to avoid exposure to moisture, as it can lead to hydrolysis and degradation of the compound.

Silver triflate has also been explored for its potential in energy-related applications. Recent research has focused on its use as an electrolyte additive in lithium-ion batteries. By incorporating silver triflate, researchers have observed improved electrochemical performance, including enhanced cycle stability and increased energy density.

In terms of environmental impact, silver triflate is considered relatively non-toxic compared to other silver compounds. However, its disposal should still adhere to standard protocols to minimize ecological risks.

In conclusion, silver triflate (CAS 2966-50-9) remains a valuable compound with diverse applications across multiple disciplines. Its role as a catalyst and precursor continues to evolve with advancements in synthetic methodologies and materials science.

• 2923-17-3(Lithium trifluoroacetate)
• 599-00-8(Trifluoroacetic Acid-d)
• 16424-89-8(Acetic acid,2,2,2-trifluoro-, tin(4+) salt (4:1))
• 16083-14-0(Nickel(2+) trifluoroacetate)
• 38482-84-7(Acetic acid, trifluoro-, magnesium salt)
• 37737-28-3(YttriumTrifluoroacetate (~90%))
• 2923-15-1(Acetic acid,2,2,2-trifluoro-, mercury(1+) salt (1:1))
• 21907-47-1(Acetic acid,2,2,2-trifluoro-, zinc salt (2:1))
• 14477-72-6(Acetic acid,2,2,2-trifluoro-, ion(1-))
• 286425-32-9(Sodium Trifluoroacetate-13C)