产量(工程)
丁烷
流动化学
化学
生产力
流量(数学)
戒指(化学)
爆炸物
间歇式反应器
光化学
有机化学
热力学
机械
催化作用
物理
宏观经济学
经济
作者
Luke D. Elliott,Jonathan P. Knowles,Paul J. Koovits,Katie G. Maskill,Michael J. Ralph,Guillaume Lejeune,Lee J. Edwards,Richard I. Robinson,Ian R. Clemens,Brian J. Cox,David D. Pascoe,Guido Koch,Martin Eberle,Malcolm B. Berry,Kevin I. Booker‐Milburn
标识
DOI:10.1002/chem.201404347
摘要
The use of flow photochemistry and its apparent superiority over batch has been reported by a number of groups in recent years. To rigorously determine whether flow does indeed have an advantage over batch, a broad range of synthetic photochemical transformations were optimized in both reactor modes and their yields and productivities compared. Surprisingly, yields were essentially identical in all comparative cases. Even more revealing was the observation that the productivity of flow reactors varied very little to that of their batch counterparts when the key reaction parameters were matched. Those with a single layer of fluorinated ethylene propylene (FEP) had an average productivity 20% lower than that of batch, whereas three-layer reactors were 20% more productive. Finally, the utility of flow chemistry was demonstrated in the scale-up of the ring-opening reaction of a potentially explosive [1.1.1] propellane with butane-2,3-dione.
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