Continuous Photo-Oxidation in a Vortex Reactor: Efficient Operations Using Air Drawn from the Laboratory

Lee, Darren S.; Amara, Zacharias; Clark, Charlotte A.; Xu, Zeyuan; Kakimpa, Bruce; Morvan, Hervé; Pickering, Simon; Poliakoff, Martyn; George, Michael W.

doi:10.1021/acs.oprd.7b00153

Cited by 68 publications

(76 citation statements)

References 72 publications

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“…To solve these problems both the surface area of the reaction solution that is exposed to light and the gas‐liquid interface surface area should be maximized. Examples of how one, or sometimes both, these surface areas have been maximized include; using lengths of flexible tubing wrapped around the light source (fluorinated ethylene propylene‐FEP tubing,– perfluoroalkoxy‐PFA tubing,,, microcapilliary,,,, parallel systems,), thin‐walled annular vessels, falling films, thin film, gas‐liquid membranes, vortexes or mesofluidic devices . In our system (Figure ), very high specific surface areas (conservatively estimated to be in the range of 100,000 to 1,000,000 m 2 m −3[7a,14] ) have been attained by nebulizing the reaction solution.…”

Section: Methodsmentioning

confidence: 98%

One‐Pot Synthesis of Diverse γ‐Lactam Scaffolds Facilitated by a Nebulizer‐Based Continuous Flow Photoreactor

et al. 2018

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The use of a modified prototype continuous flow reactor (CFR) as a pivotal part of a number of versatile singlet oxygen‐mediated reaction sequences is presented herein. These sequences target rapid access to structural complexity and diversity. The prototype reactor achieves high conversions and productivities by attaining large specific surface areas for these biphasic reactions. In the reactor, the reaction solution is nebulized (using either oxygen or air) and the resulting aerosol is irradiated by an LED jacket that surrounds the Pyrex reaction chamber. The one pot procedures developed herein are, according to many different criteria, both highly efficient and green. The key common intermediates and the source of both the complexity and variety of the final products are N‐acyl imminium ions (NAI; protonated N‐acyl enamines). The initial substrates are simple and readily accessible furans and the diverse array of products is composed of different complex γ‐lactams. Many of the products are of particular interest due to their close relationships to known biologically active molecules.

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Section: Methodsmentioning

confidence: 98%

One‐Pot Synthesis of Diverse γ‐Lactam Scaffolds Facilitated by a Nebulizer‐Based Continuous Flow Photoreactor

et al. 2018

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“…In this case a rapid rotation generates a Taylor vortices flow presenting certain advantages for gas/liquid heterogeneous reactions. 41 The high mass transfer between both layers allows a more efficient dissolution of gases, owing to which air from the lab can be used instead of pressurized oxygen. The versatile application of a vortex reactor could be demonstrated in different photochemical reactions using 1…”

Section: Flow Photochemistrymentioning

confidence: 99%

Light on the Horizon: Current Research and Future Perspectives in Flow Photochemistry

Politano

Oksdath‐Mansilla

2018

Org. Process Res. Dev.

142

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The research area of synthetic organic photochemistry is a powerful tool for creating both natural products and molecules with high structural complexity, in a simple way and under mild conditions. However, because of the challenges in scaling-up, it has been difficult to apply a photochemical reaction in an industrial process. Flow chemistry provides an opportunity for better control over the conditions of the reaction and, additionally, improved reaction selectivity and enhanced reproducibility. Taking into account that significant interest has focused on the use of flow photochemistry as a method for the synthesis of heterocycles and its applications in target-oriented synthesis over the last few years, the aim of this review is to highlight the recent efforts to apply flow photochemistry methodology to diverse reactions as a greener and more scalable process for the pharmaceutical and fine chemical industries. Additionally, the review highlights future perspectives in the development of scale-up strategies, combining photochemical reactions in the continuous flow multistep synthesis of organic molecules, being of interest for scientists and engineers alike.

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“…Further process intensification can be achieved through continuous flow reactors . Furthermore, several recent publications illustrate the benefits of advanced reactor concepts, e.g., packed‐bed‐, pneumatic nebulizer‐, slug flow, annular flow, vortex or luminescent solar concentrator reactors .…”

Section: Example 3 – Reaction Engineering Of Photochemical Processesmentioning

confidence: 99%

Process Intensification – An Unbroken Trend in Chemical Engineering

Grützner

Ziegenbalg

Güttel

2018

Chemie Ingenieur Technik

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Process intensification is one of the major strategies in chemical engineering to cope with the steadily increasing demands to design and operate a chemical process as efficient and sustainable as possible. Research on this field reaches back to the middle of the last century and is still an important area of activity for chemical engineers in both, academia and practice. This contribution provides a rough overview on the history of process intensification, highlights three current examples of research (multiple dividing wall column, nanostructured core‐shell catalysts, photocatalytic reactions) and closes with a brief outlook to future activities.

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Continuous Photo-Oxidation in a Vortex Reactor: Efficient Operations Using Air Drawn from the Laboratory

Cited by 68 publications

References 72 publications

One‐Pot Synthesis of Diverse γ‐Lactam Scaffolds Facilitated by a Nebulizer‐Based Continuous Flow Photoreactor

One‐Pot Synthesis of Diverse γ‐Lactam Scaffolds Facilitated by a Nebulizer‐Based Continuous Flow Photoreactor

Light on the Horizon: Current Research and Future Perspectives in Flow Photochemistry

Process Intensification – An Unbroken Trend in Chemical Engineering

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