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  Eléonore Resongles,Corinne Casiot,Fran?oise Elbaz-Poulichet,Rémi Freydier,Odile Bruneel,Christine Piot,Sophie Delpoux,Aurélie Volant,Angélique Desoeuvre Environ. Sci.: Processes Impacts, 2013,15, 1536-1544
• 2. Excimer and exciplex formation in a pair of bright phosphorescent isomers constructed from Cu3(pyrazolate)3 and Cu3I3 coordination luminophores?
  Shun-Ze Zhan,Mian Li,Xiao-Ping Zhou,Dan Li,Seik Weng Ng RSC Adv., 2011,1, 1457-1459
• 3. Establishing empirical design rules of nucleic acid templates for the synthesis of silver nanoclusters with tunable photoluminescence and functionalities towards targeted bioimaging applications?
  Jason Y. C. Lim,Yong Yu,Guorui Jin,Kai Li,Yi Lu,Jianping Xie Nanoscale Adv., 2020,2, 3921-3932
• 4. Excitable dynamics in the bromate–sulfite–ferrocyanide reaction
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  Olga Guselnikova,Gérard Audran,Jean-Patrick Joly,Andrii Trelin,Evgeny V. Tretyakov,Vaclav Svorcik,Oleksiy Lyutakov,Sylvain R. A. Marque Chem. Sci., 2021,12, 4154-4161

• Solvents and Organic Chemicals Organic Compounds Benzenoids Phenanthrenes and derivatives Phenanthrenes and derivatives
• Solvents and Organic Chemicals Organic Compounds Benzenoids Phenanthrenes and derivatives

Comprehensive Analysis of 3,10-Dibromoperylene (CAS No. 85514-20-1): Properties, Applications, and Industry Trends

3,10-Dibromoperylene (CAS No. 85514-20-1) is a brominated derivative of perylene, a polycyclic aromatic hydrocarbon (PAH) with significant industrial and research applications. This compound is characterized by its distinct molecular structure, which includes two bromine atoms attached to the perylene backbone at the 3 and 10 positions. The presence of bromine enhances its electronic properties, making it a valuable material in organic electronics, photovoltaics, and advanced material science.

One of the most notable features of 3,10-Dibromoperylene is its role in organic semiconductors. With the growing demand for flexible and lightweight electronic devices, researchers are increasingly exploring this compound for its potential in OLEDs (Organic Light-Emitting Diodes) and OPVs (Organic Photovoltaics). Its ability to facilitate charge transport and stability under various environmental conditions makes it a promising candidate for next-generation green energy solutions.

In addition to its electronic applications, 3,10-Dibromoperylene is also studied for its fluorescence properties. The compound exhibits strong emission in the visible spectrum, which is highly sought after in bioimaging and sensor technologies. Recent advancements in nanotechnology have further expanded its utility, enabling the development of high-performance sensors for environmental monitoring and medical diagnostics.

The synthesis of 3,10-Dibromoperylene typically involves the bromination of perylene under controlled conditions. This process requires precise reaction optimization to achieve high yields and purity, which are critical for industrial-scale production. Researchers are also investigating alternative synthetic routes to reduce costs and improve sustainability, aligning with the global push toward green chemistry.

From a commercial perspective, the demand for 3,10-Dibromoperylene is driven by its versatility and performance in niche markets. Companies specializing in advanced materials and electronic components are actively investing in R&D to harness its full potential. Furthermore, regulatory frameworks emphasizing eco-friendly materials are likely to bolster its adoption in the coming years.

In summary, 3,10-Dibromoperylene (CAS No. 85514-20-1) stands at the intersection of innovation and practicality. Its unique properties and broad applicability make it a focal point for researchers and industry leaders alike. As technology continues to evolve, this compound is poised to play a pivotal role in shaping the future of organic electronics and sustainable materials.

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