For research and development teams in the chemical sciences, access to high-quality, specialized reagents is fundamental to innovation. 1,3,6,8-Tetrachloropyrene, identified by its CAS number 81-29-8, is one such compound that garners attention due to its unique chemical structure and reactivity. As a chemical supplier dedicated to supporting R&D efforts, we understand the critical need for reliable access to compounds like this. This article outlines the properties and research relevance of 1,3,6,8-Tetrachloropyrene, guiding scientists and procurement specialists on how to best source it.

The Chemical Profile of 1,3,6,8-Tetrachloropyrene

1,3,6,8-Tetrachloropyrene, with the molecular formula C16H6Cl4 and EINECS 201-340-4, is a derivative of pyrene featuring four chlorine substituents. These chlorine atoms are strategically placed, rendering the molecule particularly interesting for synthetic chemists. Its high melting point of 368 °C means it exists as a stable solid, making it generally easy to handle in a laboratory setting. Safety information, such as hazard classifications (e.g., H413, H302), is important for R&D personnel to be aware of, ensuring appropriate laboratory practices are followed. When research scientists search to 'buy 1,3,6,8-tetrachloropyrene', they are often looking for compounds that meet specific purity criteria essential for reproducible experimental results.

Why is 1,3,6,8-Tetrachloropyrene Valued in R&D?

The primary value of 1,3,6,8-Tetrachloropyrene in R&D settings stems from its potential as a versatile synthetic intermediate. Its structure allows for various chemical modifications:

  • Platform for Functionalization: The chlorine atoms can be replaced with other functional groups through reactions like palladium-catalyzed cross-couplings (e.g., Suzuki, Sonogashira), enabling the synthesis of complex polycyclic aromatic systems.
  • Development of Novel Materials: Researchers may use it as a starting point for creating new organic electronic materials, fluorescent probes, or specialized polymers where the chlorinated pyrene core imparts desired properties.
  • Exploration of Reaction Chemistry: Its defined structure and known reactivity make it a useful model compound for investigating new synthetic methodologies or catalysis.

For research teams, sourcing from a dependable '1,3,6,8-tetrachloropyrene supplier' ensures that the starting material is of consistent quality, which is critical for the validity of experimental outcomes. Comparing the 'price' for research quantities from various 'manufacturers in China' is common practice.

Sourcing for Research: What to Look For

When procuring 1,3,6,8-Tetrachloropyrene for R&D purposes, attention to detail is key:

  • Purity: For research, high purity is often essential. Always request a Certificate of Analysis (CoA) to confirm the compound meets your purity requirements.
  • Availability: Ensure the supplier has sufficient stock for your immediate needs or can provide reliable lead times for future orders.
  • Documentation: Beyond the CoA, access to safety data sheets (SDS) and any available technical notes is beneficial.
  • Supplier Reputation: Partnering with a known and trusted chemical supplier, especially one that specializes in fine chemicals for R&D, minimizes risks associated with product quality and delivery.

Many research institutions and chemical companies actively search for a 'C16H6Cl4 supplier' that understands the specific demands of the R&D sector. Leveraging manufacturers who specialize in fine chemicals can provide access to both quality products and valuable technical insights.

In conclusion, 1,3,6,8-Tetrachloropyrene (CAS 81-29-8) is a valuable tool for researchers engaged in advanced chemical synthesis and material science. By understanding its properties and choosing a competent supplier, R&D professionals can effectively acquire this key intermediate to drive their innovative projects forward.