1-Phenyl-2-nitropropene An Overview of Suppliers and Applications

1-Phenyl-2-nitropropene, with the CAS number 705-60-2, is a compound of increasing interest in various fields, particularly in organic chemistry and pharmaceuticals. Its unique structure, featuring a phenyl group attached to a nitro-substituted propene, makes it a key intermediate for synthesizing a variety of organic compounds. This article aims to provide an overview of this chemical, its applications, and insights into potential suppliers.

Chemical Properties and Structure

The chemical formula for 1-phenyl-2-nitropropene is C10H11NO2. It possesses a nitro group (-NO2) which is known for its electron-withdrawing properties, making the compound reactive in various chemical reactions. The structure consists of a phenyl ring (C6H5) bonded to a 2-nitropropene group, which imparts the compound with significant reactivity, particularly in electrophilic aromatic substitution reactions and Michael additions. Understanding its properties is crucial for chemists looking to utilize this compound in synthesis.

1-Phenyl-2-nitropropene is predominantly used as an intermediate in the synthesis of pharmaceuticals and agrochemicals. One of its notable applications is in the production of various pharmaceuticals, particularly in the synthesis of certain antihistamines and anti-inflammatory medications. Its reactivity allows for straightforward derivatization, enabling chemists to create a wide range of compounds.

Additionally, the compound is utilized in material science for generating polymers with improved properties. For instance, incorporating nitroalkene derivatives can vastly enhance the material's thermal stability and mechanical strength. As demand for high-performance materials grows, the role of 1-phenyl-2-nitropropene in this sector is likely to expand.

Sourcing 1-Phenyl-2-nitropropene

When searching for suppliers of 1-phenyl-2-nitropropene, it is important to consider both quality and reliability. Various chemical suppliers and manufacturers across the globe offer this compound. Notable suppliers typically include bulk chemical manufacturers and specialized organic compound providers.

1. Chemical Supply Companies Leading chemical supply companies often have extensive catalogs that include both common and rare organic compounds. These suppliers prioritize quality control and regulatory compliance, ensuring that the products meet the necessary safety and quality standards. Some notable names in this space include Sigma-Aldrich, TCI Chemicals, and Alfa Aesar. They provide comprehensive data sheets including safety information, MSDS, and specifications for their products.

2. Online Marketplaces Online chemical marketplaces have become increasingly popular for sourcing specialty chemicals. Platforms like ChemSpider or Alibaba may list various suppliers for 1-phenyl-2-nitropropene, giving buyers the option to compare prices, verify supplier credibility, and review product specifications. This accessibility has made it easier for small businesses and laboratories to obtain necessary chemicals without needing large-scale purchasing capacity.

3. Custom Synthesis Services For specific needs that go beyond off-the-shelf products, many chemical companies also offer custom synthesis services. If the required quantity is significant or if unique substitutions or modifications are desired, engaging with a supplier that specializes in custom synthesis can be advantageous. These suppliers leverage their expertise to create tailor-made solutions for their clients.

Conclusion

1-Phenyl-2-nitropropene is a valuable compound in organic synthesis, with applications ranging from pharmaceuticals to advanced materials. As industry demand increases, sourcing quality materials becomes paramount. Chemical supply companies, online marketplaces, and custom synthesis services present a variety of pathways for sourcing this compound. Continued research and development surrounding 1-phenyl-2-nitropropene may lead to new applications and improvements in manufacturing processes, reinforcing its significance in modern chemistry. By understanding its properties and potential, researchers and manufacturers can effectively capitalize on its benefits.