Applications of Flow Microreactors in Electrosynthetic Processes

Atobe, Mahito; Tateno, Hiroyuki; Matsumura, Yoshihito

doi:10.1021/acs.chemrev.7b00353

Cited by 310 publications

(189 citation statements)

References 132 publications

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“…[3] Organic electrochemistry is ap owerful method for organic synthesis,b ut there are also limitations for electrochemistry in batch processes.A sc ommon organic solvents have typically low conductivity,t he use and subsequent removal of supporting electrolytes is necessary.T he large distance between electrodes in batch processes leads to large current gradients.Continuous flow reactors can address some of these problems. [4] Small electrode distances avoid large current gradients and reactions can be performed with small amounts or even without addition of supporting electrolytes, although modification of electrode surfaces has also been investigated. [5] Ah igh electrode surface-to-reactor volume ratio allows amuch improved mass transfer on the surface of the electrodes leading to milder reaction conditions and short reaction times.…”

mentioning

confidence: 99%

An Easy‐to‐Machine Electrochemical Flow Microreactor: Efficient Synthesis of Isoindolinone and Flow Functionalization

et al. 2017

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Flow electrochemistry is an efficient methodology to generate radical intermediates. An electrochemical flow microreactor has been designed and manufactured to improve the efficiency of electrochemical flow reactions. With this device only little or no supporting electrolytes are needed, making processes less costly and enabling easier purification. This is demonstrated by the facile synthesis of amidyl radicals used in intramolecular hydroaminations to produce isoindolinones. The combination with inline mass spectrometry facilitates a much easier combination of chemical steps in a single flow process.

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confidence: 99%

An Easy‐to‐Machine Electrochemical Flow Microreactor: Efficient Synthesis of Isoindolinone and Flow Functionalization

et al. 2017

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“…Biphasic reaction conditions (acetonitrile/1 M HCl) are required and the reaction was carried out in batch. However, preliminary studies showed that the use of flow chemistry was of great benefit [16][17][18][19][20]. The reaction time could be reduced to the minute range in flow and no mass transfer limitations were observed.…”

Section: Introductionmentioning

confidence: 99%

Accelerating sulfonyl fluoride synthesis through electrochemical oxidative coupling of thiols and potassium fluoride in flow

et al. 2020

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Sulfonyl fluorides are valuable synthetic motifs which are currently of high interest due to the popularity of the sulfur (VI) fluoride exchange (SuFEx) click chemistry concept. Herein, we describe a flow chemistry approach to enable their synthesis through an electrochemical oxidative coupling of thiols and potassium fluoride. The reaction can be carried out at room temperature and atmospheric pressure and the yield of the targeted sulfonyl fluoride, by virtue of the short inter-electrode distance between a graphite anode and a stainless-steel cathode, reached up to 92% in only 5 min residence time compared to 6 to 36 h in batch. A diverse set of thiols (7 examples) was subsequently converted in flow. Finally, a fully telescoped process was developed which combines the electrochemical sulfonyl fluoride synthesis with a follow-up SuFEx reaction.

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“…On the other hand, flow electrochemistry offers many advantageso ver batch electrochemistry. [18,[36][37][38][39][40][41][42][43] For example, al arge ratio of electrode surface to reactor volume reduces the reaction time. In addition, the short distance between electrodes enables am ore efficient mass transfer and allows the use of low concentrations of supporting electrolyte or even no supporting electrolyte at all.…”

Section: Introductionmentioning

confidence: 99%

Catalyst‐ and Supporting‐Electrolyte‐Free Electrosynthesis of Benzothiazoles and Thiazolopyridines in Continuous Flow

Folgueiras‐Amador

Qian

et al. 2017

Chemistry A European J

114

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A catalyst- and supporting electrolyte-free method for electrochemical dehydrogenative C-S bond formation in continuous flow has been developed. A broad range of N-arylthioamides have been converted to the corresponding benzothiazoles in good to excellent yields and with high current efficiencies. This transformation is achieved using only electricity and laboratory grade solvent, avoiding degassing or the use of inert atmosphere. This work highlights three advantages of electrochemistry in flow, which is (i) a supporting electrolyte-free reaction, (ii) an easy scale-up of the reaction without the need for a larger reactor and, (iii) the important and effective impact of having a good mixing of the reaction mixture, which can be achieved effectively with the use of flow systems. This clearly improves the reported methods for the synthesis of benzothiazoles.

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Applications of Flow Microreactors in Electrosynthetic Processes

Cited by 310 publications

References 132 publications

An Easy‐to‐Machine Electrochemical Flow Microreactor: Efficient Synthesis of Isoindolinone and Flow Functionalization

An Easy‐to‐Machine Electrochemical Flow Microreactor: Efficient Synthesis of Isoindolinone and Flow Functionalization

Accelerating sulfonyl fluoride synthesis through electrochemical oxidative coupling of thiols and potassium fluoride in flow

Catalyst‐ and Supporting‐Electrolyte‐Free Electrosynthesis of Benzothiazoles and Thiazolopyridines in Continuous Flow

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