Beyond its established role in peptide synthesis, Ethyl 2-Oximinooxamate (CAS 10489-74-4), available from NINGBO INNO PHARMCHEM CO.,LTD., exhibits significant utility in the fields of catalysis and coordination chemistry. Its unique structural features enable it to act as a ligand and participate in catalytic cycles, opening up new avenues for efficient chemical transformations.

The oxime moiety within Ethyl 2-Oximinooxamate is particularly adept at coordinating with transition metal ions, such as copper and iron. This coordination capability allows it to form stable metal complexes, which can then serve as catalysts or model systems for studying metalloenzymes. For instance, copper-oxamate complexes have been investigated for their catalytic activity in various organic reactions, including cross-coupling reactions. The ability to form these complexes highlights its importance in coordination chemistry.

In catalytic applications, Ethyl 2-Oximinooxamate, often in its role as a ligand, can influence the reactivity and selectivity of metal catalysts. Copper-oxamate systems, for example, have shown promise in catalyzing the cross-coupling of alpha-branched amines with aryl halides. This streamlining of drug synthesis pathways is a significant contribution to medicinal chemistry and process development. The study of catalysis with Ethyl 2-Oximinooxamate reveals its potential in creating more efficient synthetic routes.

Furthermore, the electronic properties imparted by the oxime and ester groups allow for fine-tuning of the catalytic activity. By understanding the precise interactions between the metal center and the Ethyl 2-Oximinooxamate ligand, researchers can design more efficient and selective catalytic systems. This molecular-level understanding is key to advancing green chemistry and developing more sustainable industrial processes.

NINGBO INNO PHARMCHEM CO.,LTD. provides high-purity Ethyl 2-Oximinooxamate, supporting researchers in exploring its catalytic and coordination chemistry applications. By providing this essential building block, we aim to facilitate innovation in areas ranging from new synthetic methodologies to the development of advanced materials. The exploration of metal complexes of Ethyl 2-Oximinooxamate continues to unveil new possibilities in catalysis.