(5-BroMothiazol-2-yl)Methanol

Unlock the versatile potential of (5-BroMothiazol-2-yl)Methanol, a highly specialized chemical compound that holds the key to unlocking new frontiers in scientific research and development. With its unique molecular structure and exceptional purity, this compound is poised to become an indispensable tool in the hands of discerning researchers and innovators.

At the heart of this compound lies a captivating combination of elements, including bromine, sulfur, and nitrogen, all meticulously arranged to create a molecule with remarkable properties. The CAS number 911052-85-2 serves as a unique identifier, while the Ref # AN-AG00H0YO provides a convenient reference point for those seeking detailed information.

Delving deeper into the technical specifications, we find that (5-BroMothiazol-2-yl)Methanol boasts a molecular formula of C4H4BrNOS, with a molecular weight of 194.0497 g/mol. Its purity, meticulously maintained at 95%, ensures consistent and reliable results in even the most demanding research applications. The compound's distinct solid form and pale color further contribute to its visual appeal and ease of handling.

But the true value of (5-BroMothiazol-2-yl)Methanol lies in its versatility and the myriad of possibilities it unlocks for researchers and innovators. Whether you're exploring the frontiers of pharmaceutical development, pushing the boundaries of agrochemical innovation, or seeking to create novel materials with tailored properties, this compound is poised to be your indispensable ally.

Pharmaceutical Research: Unlocking New Therapeutic Avenues

In the realm of pharmaceutical research, (5-BroMothiazol-2-yl)Methanol shines as a crucial building block in the synthesis of innovative drug candidates. Its unique molecular structure and chemical properties allow researchers to explore new therapeutic pathways, targeting a wide range of health conditions and disorders. From neurological disorders to metabolic diseases, this compound holds the potential to unlock groundbreaking advancements in the field of medicine.

By leveraging the versatility of (5-BroMothiazol-2-yl)Methanol, researchers can design and develop novel compounds with enhanced pharmacological profiles, improved bioavailability, and targeted mechanisms of action. The compound's adaptability to various synthetic strategies enables the creation of a diverse array of drug candidates, each with the promise of addressing unmet medical needs and improving patient outcomes.

Agrochemical Innovation: Cultivating a Healthier Future

Beyond the realm of pharmaceuticals, (5-BroMothiazol-2-yl)Methanol also finds its place in the dynamic world of agrochemicals. Its unique chemical structure and properties make it a valuable building block in the development of advanced crop protection agents, helping to safeguard the health and productivity of agricultural crops.

By incorporating (5-BroMothiazol-2-yl)Methanol into the synthesis of innovative pesticides and herbicides, researchers can create more potent and selective formulations. These cutting-edge agrochemicals not only enhance crop yields but also minimize environmental impact, promoting a sustainable and eco-friendly approach to modern agriculture.

Material Science Innovations: Unlocking New Possibilities

The versatility of (5-BroMothiazol-2-yl)Methanol extends beyond the realms of pharmaceuticals and agrochemicals, as it also finds application in the exciting field of material science. Researchers in this domain can leverage the compound's distinct chemical properties to engineer novel materials with enhanced performance characteristics, such as improved mechanical strength, thermal stability, or optical properties.

By incorporating (5-BroMothiazol-2-yl)Methanol into the synthesis of advanced polymers, coatings, or other functional materials, scientists can unlock new possibilities in areas like energy storage, electronics, and beyond. The compound's adaptability to various synthetic strategies allows for the creation of tailored materials with unique and desirable attributes, driving innovation and progress in the material science