Continuous Flow Organic Chemistry: Successes and Pitfalls at the Interface with Current Societal Challenges

Gérardy, Romaric; Emmanuel, Noémie; Toupy, Thomas; Kassin, Victor-Emmanuel; Tshibalonza, Nelly Ntumba; Schmitz, Michaël; Monbaliu, Jean‐Christophe M.

doi:10.1002/ejoc.201800149

Cited by 208 publications

(117 citation statements)

References 283 publications

(335 reference statements)

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“…Moreover, the mass and heat control guaranteed by the flow process can allow the tunability of the reaction products. 20,21 Additionally, the development of Fig. 1 Lignocellulosic biomass composition and hydrogenation of its derivatives, i.e., glucose (Glu) hydrogenation to Sorbitol (Sor) as cellulose-derived process, hemicellulose derived compounds, Xylose (Xyl) conversion to Xylitol (Xyt), and the hydrogenation of Vanillin (V), from lignin, to 2-methoxy-4methylphenol (MMP) through Vanillyl alcohol (VA).…”

Section: Introductionmentioning

confidence: 99%

Nickel on nitrogen-doped carbon pellets for continuous-flow hydrogenation of biomass-derived compounds in water

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Section: Introductionmentioning

confidence: 99%

Nickel on nitrogen-doped carbon pellets for continuous-flow hydrogenation of biomass-derived compounds in water

et al. 2020

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“…The challenges associated with handling O 2 are better addressed by using continuous processing than multipurpose batch reactors [7,8]. There is a current paradigm shift in the pharmaceutical industry from traditional batch manufacturing to continuous processing for the preparation of active pharmaceutical ingredients (APIs) [9][10][11][12]. This paradigm shift is reflected by a new focus in the pharmaceutical industry on process intensification, sustainability, product quality, safety, energy usage and cost [13].…”

Section: Introductionmentioning

confidence: 99%

The Use of Molecular Oxygen for Liquid Phase Aerobic Oxidations in Continuous Flow

Hone¹,

Kappe²

2018

Topics in Current Chemistry Collections

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Molecular oxygen (O 2) is the ultimate "green" oxidant for organic synthesis. There has been recent intensive research within the synthetic community to develop new selective liquid phase aerobic oxidation methodologies as a response to the necessity to reduce the environmental impact of chemical synthesis and manufacture. Green and sustainable chemical processes rely not only on effective chemistry but also on the implementation of reactor technologies that enhance reaction performance and overall safety. Continuous flow reactors have facilitated safer and more efficient utilization of O 2 , whilst enabling protocols to be scalable. In this article, we discuss recent advancements in the utilization of continuous processing for aerobic oxidations. The translation of aerobic oxidation from batch protocols to continuous flow processes, including process intensification (high T/p), is examined. The use of "synthetic air", typically consisting of less than 10% O 2 in N 2 , is compared to pure O 2 (100% O 2) as an oxidant source in terms of process efficiency and safety. Examples of homogeneous catalysis and heterogeneous (packed bed) catalysis are provided. The application of flow photoreactors for the in situ formation of singlet oxygen (1 O 2) for use in organic reactions, as well as the implementation of membrane technologies, green solvents and recent reactor solutions for handling O 2 are covered.

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“…[23][24][25] With its potential to overcome some of the common issues encountered with batch protocols, flow chemistry has thrived in the many research areas inherent of or at the interface with Organic Chemistry, including methodology, medicinal chemistry, total synthesis, physical organic chemistry and process chemistry to name a few. [26][27][28][29][30][31][32][33][34][35][36] Organophosphorus reagents are widespread for a wide range of reference reactions and organophosphorus chemistry has so many ties towards industrial applications with immense markets and volumes, including pharmaceuticals and agrochemicals. It is therefore not surprising to witness a revisit of organophosphorus chemistry by flow chemists with unquestionable advantages.…”

Section: Introductionmentioning

confidence: 99%

Continuous Flow Organophosphorus Chemistry

2020

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Organophosphorus derivatives are widespread compounds that chemists find from the bench to the plant, with numerous daily life applications. Besides their common utility for a wide range of notorious reactions such as the Wittig and Horner‐Wadsworth‐Emmons olefinations, the Arbuzov reaction, the Staudinger reaction, the Mitsunobu reaction as well as ligands for a large variety of organometallic complexes, organophosphorus compounds have also found numerous applications as active pharmaceutical ingredients and agrochemicals. Some organophosphorus derivatives are also infamously known as Chemical Warfare Agents. Within the context of generalized adoption of new process technologies in the Chemistry Toolbox, this review intends to give an update on the most recent and significant advances in continuous flow organophosphorus chemistry. Selected examples in methodology, total synthesis and for the preparation of industrially relevant targets are discussed for illustrating the assets of flow chemistry.

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Continuous Flow Organic Chemistry: Successes and Pitfalls at the Interface with Current Societal Challenges

Cited by 208 publications

References 283 publications

Nickel on nitrogen-doped carbon pellets for continuous-flow hydrogenation of biomass-derived compounds in water

Nickel on nitrogen-doped carbon pellets for continuous-flow hydrogenation of biomass-derived compounds in water

The Use of Molecular Oxygen for Liquid Phase Aerobic Oxidations in Continuous Flow

Continuous Flow Organophosphorus Chemistry

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