Understanding the fundamental chemical properties of a compound is key to unlocking its full potential in various industrial applications. Diphenylglycine, bearing the CAS number 3060-50-2, is a molecule of significant interest within the chemical community. Its structure, characterized by two phenyl groups attached to the alpha carbon of glycine, imparts unique reactivity and stability. Often referred to by synonyms such as 2,2-Diphenylglycine or α,α-Diphenylglycine, this compound serves as a vital intermediate in multiple synthesis pathways, underscoring its role in advancing Fine Chemical Synthesis Technologies.

The molecular formula of Diphenylglycine is C14H13NO2, with a molecular weight of 227.2585. This specific composition dictates its behavior in chemical reactions, making it suitable for a range of transformations. Its appearance as a white powder further aids in its handling and quality assessment, with suppliers typically guaranteeing a purity of ≥99%. This high level of purity is not merely a quantitative measure; it is a qualitative assurance that the material is free from impurities that could hinder complex reactions or compromise the integrity of final products, such as APIs/Intermediate.

The applications for Diphenylglycine are broad and continue to expand. It is prominently used as a pharmaceutical intermediate, contributing to the creation of Active Pharmaceutical Ingredients (APIs) that are essential for modern medicine. Beyond pharmaceuticals, it finds utility in the synthesis of other fine chemicals and specialty materials. The ability to buy this compound from reliable pharmaceutical intermediate manufacturers in China, like NINGBO INNO PHARMCHEM CO.,LTD., ensures that researchers and production managers have access to a consistent and high-quality supply. This makes it easier to plan for processes like Amino-diphenylacetic acid synthesis.

Exploring the chemical properties of CAS 3060-50-2 also reveals its potential in academic research and industrial process development. Its well-defined structure makes it a valuable model compound for studying reaction mechanisms or developing new synthetic methodologies. For any organization involved in the chemical sciences, understanding and utilizing compounds like Diphenylglycine is fundamental to innovation and progress. The ongoing demand for novel materials and therapeutics ensures that this intermediate will continue to be a focus of chemical innovation.