Flow Photochemistry as a Tool in Organic Synthesis

Rehm, Thomas H.

doi:10.1002/chem.202000381

Cited by 94 publications

(59 citation statements)

References 257 publications

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“…Over the last decade continuous flow photochemistry has matured into a powerful field within synthetic organic chemistry. Key features that enable effective photochemical transformations in flow mode are the ability to uniformly irradiate solutions of substrates that are continuously pumped through narrow diameter tubing or microchannels [1][2][3]. High spatiotemporal control furthermore allows the effects from overirradiation to easily be minimised as in principle each molecule resides within the irradiated section of the flow reactor for the same amount of time, which can be controlled with high precision in flow mode [4].…”

Section: Introductionmentioning

confidence: 99%

Scalability of photochemical reactions in continuous flow mode

2021

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Continuous flow photochemistry as a field has witnessed an increasing popularity over the last decade in both academia and industry. Key drivers for this development are safety, practicality as well as the ability to rapidly access complex chemical structures. Continuous flow reactors, whether home-built or from commercial suppliers, additionally allow for creating valuable target compounds in a reproducible and automatable manner. Recent years have furthermore seen the advent of new energy efficient LED lamps that in combination with innovative reactor designs provide a powerful means to increasing both the practicality and productivity of modern photochemical flow reactors. In this review article we wish to highlight key achievements pertaining to the scalability of such continuous photochemical processes. Graphical abstract

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Section: Introductionmentioning

confidence: 99%

Scalability of photochemical reactions in continuous flow mode

2021

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“…This narrow distance is proportional to the solvent/electrolyte system's resistance and is hence highly advantageous. Inside the reactor, reaction conditions, such as temperature and pressure, are controlled, and the stream of product is either carried into a second reactor or displaced into a collection unit ( Rehm, 2020 ). The amount of time reactants spend in a flow reactor is defined by residence time and is a factor of flow rate and reactor volume (residence time = flow rate × volume).…”

Section: Continuous Flow Chemistry and Flow Electrosynthesismentioning

confidence: 99%

Bridging Lab and Industry with Flow Electrochemistry

2020

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A revitalization of organic electrosynthesis has incited the organic chemistry community to adopt electrochemistry as a green and cost-efficient method for activating small molecules to replace highly toxic and expensive redox chemicals. However, many of the critical challenges of batch electrosynthesis, especially for organic synthesis, still remain. The combination of continuous flow technology and electrochemistry is a potent means to enable industry to implement large scale electrosynthesis. Indeed, flow electrosynthesis helps overcome problems that mainly arise from macro batch electro-organic systems, such as mass transfer, ohmic drop, and selectivity, but this is still far from being a flawless and generic applicable process. As a result, a notable increase in research on methodology and hardware sophistication has emerged, and many hitherto uncharted chemistries have been achieved. To better help the commercialization of widescale electrification of organic synthesis, we highlight in this perspective the advances made in large-scale flow electrosynthesis and its future trajectory while pointing out the main challenges and key improvements of current methodologies.

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“…Continuous flow technology has attracted more and more attention in recent years, 17 and shows some significant advantages over conventional batch reactions, including the in situ formation and direct use of reaction intermediates, convenience of temperature control, increased reaction contact area, and ease of amplification. Hence, the model reactant 1a was used to study this intramolecular cyclization reaction under continuous flow conditions.…”

Section: Cluster Synlettmentioning

confidence: 99%

“…In summary, a green, mild and simple method to access fluorenone derivatives is described. A number of substituted fluorenones 17 have been synthesized via this process, which may have potential as luminescent materials. Continuous flow chemistry 18 was successfully applied in this deoxygenative intramolecular acylation, showing the potential for scale-up and possible industrialization of the process.…”

Section: Scheme 4 the Proposed Mechanismmentioning

confidence: 99%

Direct Deoxygenative Intramolecular Acylation of Biarylcarboxylic Acids

Zhu

et al. 2020

Synlett

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A photocatalyzed intramolecular cyclization is developed for the synthesis of fluorenones. In this photoredox reaction, triphenylphosphine is used as an inexpensive and effective deoxygenative reagent for biarylcarboxylic acids to give acyl radicals, which quickly undergo intramolecular radical cyclization. Reactions in the presence of air and continuous flow photoredox technology demonstrate the generality and practicality of this process.

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Flow Photochemistry as a Tool in Organic Synthesis

Cited by 94 publications

References 257 publications

Scalability of photochemical reactions in continuous flow mode

Scalability of photochemical reactions in continuous flow mode

Bridging Lab and Industry with Flow Electrochemistry

Direct Deoxygenative Intramolecular Acylation of Biarylcarboxylic Acids

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