1-(2-Nitrophenyl)-2-thiourea, bearing the CAS number 51039-84-0, is a compound that garners significant attention within the fine chemical sector. Its distinct chemical structure and reactivity make it a sought-after intermediate for a wide range of synthetic processes. As a prominent member of the thiourea family, it possesses characteristics that are highly valued in advanced chemical applications. When researchers consider its procurement, understanding its profile is paramount.

Delving into the chemical profile of 1-(2-nitrophenyl)-2-thiourea reveals its molecular formula, C7H7N3O2S, and a molecular weight of 197.21 g/mol. The compound typically presents as a white to yellow powder, with a defined melting point of 136°C. These physical attributes, along with its density of 1.524 g/cm³, provide essential data for quality control and experimental planning. Accessing this information through resources like ChemicalBook, which lists details for 51039-84-0, is a common practice for chemists.

The process for the synthesis of 1-(2-nitrophenyl)-2-thiourea is a critical aspect for manufacturers aiming to provide high-purity materials. Efficient synthetic routes ensure that the compound can be reliably produced for commercial use. This focus on synthesis is what drives innovation and makes such intermediates accessible to the global research community. Suppliers often highlight their expertise in producing these compounds to meet stringent quality standards.

The market for specialty organic intermediates is dynamic, and 1-(2-Nitrophenyl)-2-thiourea plays a vital role. Its diverse 1-(2-nitrophenyl)-2-thiourea applications are testament to its utility. From its foundational use in organic synthesis to its potential in developing new materials, its value is consistently recognized. Companies specializing in fine chemicals, such as those providing products akin to Alfa Chemical's offerings, ensure that researchers can easily obtain this compound.

Ultimately, the detailed exploration of 1-(2-Nitrophenyl)-2-thiourea’s chemical properties and synthetic pathways solidifies its position as an essential component in chemical innovation. Its ready availability and well-understood nature empower continued advancements across various scientific disciplines.