• 1. The role of amine ligands in governing film morphology and electrical properties of copper films derived from copper formate-based molecular inks
  Chantal Paquet,Thomas Lacelle,Xiangyang Liu,Bhavana Deore,Arnold J. Kell,Sylvie Lafrenière,Patrick R. L. Malenfant Nanoscale 2018 10 6911
• 2. The role of amine ligands in governing film morphology and electrical properties of copper films derived from copper formate-based molecular inks
  Chantal Paquet,Thomas Lacelle,Xiangyang Liu,Bhavana Deore,Arnold J. Kell,Sylvie Lafrenière,Patrick R. L. Malenfant Nanoscale 2018 10 6911
• 3. 269. Magnetic studies with copper(II) salts. Part IV. Remarkable magnetic behaviour of copper(II) formate and its hydrates
  R. L. Martin,Hanneke Waterman J. Chem. Soc. 1959 1359
• 4. Metal particle-free inks for printed flexible electronics
  Wendong Yang,Emil J. W. List-Kratochvil,Changhai Wang J. Mater. Chem. C 2019 7 15098
• 5. From copper(II) carboxylate to copper(II) 4-pyridylsulfonate coordination polymers as a consequence of the copper(II)-assisted oxidative cleavage of the 4,4′-dipyridyldisulfide ligand
  Rosa Carballo,Berta Covelo,Nuria Fernández-Hermida,Ana B. Lago,Ezequiel M. Vázquez-López CrystEngComm 2009 11 817

• 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

Copper(II) Formate: A Versatile Compound with Broad Applications in Modern Chemistry

Copper(II) formate, with the chemical formula Cu(HCOO)₂, is a coordination compound that has garnered significant attention in recent years due to its unique chemical properties and diverse applications. This compound is identified by the CAS No. 544-19-4, which serves as a critical identifier in chemical databases and regulatory frameworks. The molecular structure of Copper(II) formate consists of a central copper ion coordinated with formate ligands, forming a stable octahedral geometry. This structural arrangement contributes to its stability and reactivity in various chemical environments.

Recent studies have highlighted the importance of Copper(II) formate in catalytic processes. For instance, a 2023 publication in Advanced Materials demonstrated its effectiveness as a heterogeneous catalyst for the oxidation of alcohols to aldehydes. The compound's ability to facilitate electron transfer and stabilize reactive intermediates has made it a preferred choice in green chemistry applications. Researchers have also explored its role in the development of sustainable chemical processes, emphasizing its low environmental impact compared to traditional metal-based catalysts.

One of the most promising areas of Copper(II) formate research is its application in nanotechnology. A 2022 study published in Nano Letters showcased the synthesis of copper-based nanomaterials using Copper(II) formate as a precursor. These nanomaterials exhibit exceptional catalytic activity and are being investigated for use in fuel cell technologies. The compound's role in creating nanostructures with controlled morphology and high surface area has opened new avenues for its use in advanced materials science.

In the field of biological sciences, Copper(II) formate has shown potential as a biomolecule. A 2024 review article in Journal of Biological Chemistry discussed its interactions with proteins and its possible role in cellular signaling pathways. The compound's ability to modulate metal ion homeostasis in biological systems has sparked interest in its potential therapeutic applications. However, further research is needed to fully understand its biological mechanisms and safety profile.

The CAS No. 544-19-4 designation ensures that Copper(II) formate is tracked and regulated in accordance with international chemical standards. This classification is crucial for ensuring the compound's safe handling, storage, and transportation. While Copper(II) formate is not classified as a hazardous material under standard regulatory frameworks, its handling still requires adherence to best practices to prevent any potential risks.

Another area of interest is the use of Copper(II) formate in the development of new materials for energy storage. A 2023 study in Energy & Environmental Science explored its potential as a component in solid-state batteries. The compound's ability to enhance the conductivity of electrolytes and improve the stability of electrode materials has made it a candidate for next-generation energy storage solutions.

From a synthetic perspective, the preparation of Copper(II) formate involves the reaction of copper salts with formic acid under controlled conditions. This process is well-documented in the literature, and recent advancements in reaction engineering have improved the efficiency and scalability of its synthesis. Researchers are continuously exploring new methods to optimize the yield and purity of Copper(II) formate for industrial applications.

The physical properties of Copper(II) formate also play a significant role in its applications. For example, its solubility in polar solvents makes it suitable for use in aqueous solutions, which is advantageous for many chemical processes. The compound's thermal stability and resistance to decomposition under various conditions further contribute to its versatility in different environments.

Despite its many advantages, the use of Copper(II) formate is not without challenges. One of the primary concerns is the potential for leaching of copper ions into the environment, which could have ecological implications. Researchers are actively working on strategies to mitigate this risk, such as encapsulating the compound in polymer matrices or modifying its surface chemistry to enhance its stability.

Looking ahead, the future of Copper(II) formate research is likely to focus on expanding its applications in emerging fields such as biotechnology and environmental science. The compound's unique properties make it a valuable tool for addressing some of the most pressing challenges in modern chemistry. As new technologies and methodologies continue to evolve, the role of Copper(II) formate is expected to grow, offering new opportunities for innovation and discovery.

In conclusion, Copper(II) formate represents a significant advancement in the field of chemical science. Its diverse applications, from catalysis to nanotechnology, underscore its importance in modern research. The CAS No. 544-19-4 designation ensures that this compound is managed within a framework of scientific rigor and regulatory compliance. As research continues to uncover new possibilities, Copper(II) formate is poised to play an even greater role in shaping the future of chemistry.

• 26354-04-1(2-Propenoic acid, 2-hydroxyethyl ester, polymer with 1,3-butadiene and ethenylbenzene)
• 3047-59-4(Formic acid, iron(2+)salt (8CI,9CI))
• 14523-98-9(Formicacid, dimer)
• 1633-56-3(Formic Acid-13C)
• 15907-03-6(Formic acid, coppersalt (8CI,9CI))
• 54375-27-8(Oxoniumylidene, formyl-)
• 555-76-0(Formic acid, iron(3+)salt (9CI))
• 2564-86-5(Methyl, hydroxyoxo-(9CI))
• 14485-07-5(Carbon dioxide, ion(1-)(8CI,9CI))
• 22992-79-6(Cupric formate dihydrate)