![]() It can be found in the scientific literature or determined and verified experimentally. The wavelength of the required radiation depends on the source molecules. Organic intermediates such as benzyl bromides or sulphonic acids Organic halides such as methylene chloride or benzal chloride Monomers or their precursors such as acrylates or caprolactam These reaction types describe the synthesis of numerous substances such as : UV-VIS radiation is used for various types of chemical reactions, such as Whatever the most suitable solutions is, whether stirred batch reactor or a continuous flow or falling film reactor, whether the required light range is within VUV, UV or VIS we can provide the most suitable system for your application. That's what is now easily available through De Dietrich Process Systems co-operating with Peschl Ultraviolet GmbH. Specific know how regarding light emmision sources and chemical as well as mechanical engineering have to get together to provide reliable technical process solutions. ![]() The scale-up of photo processes realized in lab scale and their realization in production scale is still a challenge. Numerous technical lab scale solutions have been developed in the last decades. The photochemical induced synthesis has hence become an important option for organic synthesis routes. In contrast to thermal incitation, light-induced reactions often take place at room temperature so that thermally sensitive molecules do less decompose increasing the selectivity. Take your Flow Chemistry to the next level now with fReactor PhotoFLOW.A large number of organic syntheses are only possible by irradiation with light or are accelerated considerably. Integrating the efficiency of pipe-flow processing with the advanced mixing of a CSTR, the fReactor delivers a general “plug-and-play” setup which is well-suited to multiphasic reactions allowing chemists to explore continuous-flow processing, with little expertise required. fReactor provides an expanding platform of intuitive and flexible flow reactors for the development of materials and synthesis routes. The fReactor platform was developed by the University of Leeds and Asynt Ltd to offer an affordable entry point into the world of flow chemistry. Each module includes an individual cooling fan to ensure temperature control to the contained CSTR. You can run all five of these from just one power supply using optional splitter leads. With a fully customisable configuration possible, you can choose to use just one of these compact Photo modules on one of the 5 fReactor CSTRs, or add further Photo modules for up to five positions running simultaneously. This new addition to the Asynt fReactor Flow Chemistry platform is manufactured in the UK and currently available in two wavelengths to suit your requirements:Īvailable to purchase individually, each fReactor PhotoFLOW module is positioned over the desired fReactor position in your set-up with easy to use plug-and-glow technology. The fReactor PhotoFLOW module was developed by the University of Leeds in conjunction with Asynt and gives scientists the potential to develop and expand their Flow Chemistry work quickly and easily to include photochemistry. Read more New Photochemistry in Flow tool
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