Flow chemistry
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In flow chemistry, a chemical reaction is run in a continuously flowing stream rather than in batch production. In other words, pumps move fluid into a tube, and where tubes join one another, the fluids contact one another. If these fluids are reactive, a reaction takes place. Flow chemistry is a well-established technique for use at a large scale when manufacturing large quantities of a given material. However, it is relatively new to use it in the laboratory environment.
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[edit] Batch vs. flow
Comparing parameters in Batch vs Flow:
- Reaction stoichiometry. In batch production this is defined by the concentration of chemical reagents and their volumetric ratio. In Flow this is defined by the concentration of reagents and the ratio of their flow rate.
- Reaction time. In batch production this is determined by how long a vessel is held at a given temperature. In flow this is determined by the volume of the reactor, and the bulk flow rate.
[edit] Flow Reactor scale
It is possible to have flow reactors operating at large scale; however for use in the laboratory, channel/tube scale is likely to be in the region of 50μm to 500μm. Nonetheless, this channel scale range is sufficiently broad to allow single experiments with approximately 10 mg of starting material per observation point in a similar environment to an annual production rate of several tens of tons of material (Fast transfer from research to production). In as far as synthetic efficiency is concerned, there are a number of benefits to do with thermal and mass transfer as well as mass transport that allow chemistry to perform efficiently. For a review of synthesis benefits from enhanced physical reaction control see Microflow Synthesis and literature cited therein.
[edit] Benefits of flow
- Reaction temperature can be far above the solvent's boiling point due to easy ability to contain pressure.
- Mixing can be achieved within seconds at the smaller scales used in flow chemistry.
- The thermal mass of the fluid is typically far lower than the thermal mass of the system, so massive exotherms can be controlled.
- Position along the flowing stream and reaction time point are directly related to one another. This means that it is possible to arrange the system such that further reagents can be introduced into the flowing reaction stream at precisely the time point in the reaction that is desired.
- It is possible to arrange a flowing system such that purification is coupled with the reaction. There are three primary techniques that are used:
- Solid phase scavenging
- Chromatographic separation
- Liquid/Liquid Extraction
[edit] Other uses of flow
It is possible to run experiments in flow using more sophisticated techniques, such as solid phase chemistries. Professor Steven Ley's group at Cambridge University has pioneered work that has demonstrated how valuable the coupling of flow chemistry and solid supported chemistries can be http://leygroup.ch.cam.ac.uk[1]
[edit] Running flow experiments
The practicalties of running flow experiments in normal chemistry laboratories are not simple. It requires the coupling of a range of tools that are not so commonly used by chemists. Additionally it is extremely beneficial have a software control system to help manage all of the systems that are allowing the experiment to be performed. The chemist needs to have access to specialist microfabricated devices, tubing connectors and tubing as well as the pumps to displace the reagents.
As a chemist starts to perform experiments it quickly becomes clear that the challenge of controlling the system is more complex than originally anticipated.
