Development of a Continuous‐Flow System for Catalysis with Palladium(0) Particles

Solodenko, Wladimir; Wen, Hongliang; Leue, Stefanie; Stuhlmann, Friedrich; Sourkouni-Argirusi, Georgia; Jas, Gerhard; Schönfeld, Hagen; Kunz, Ulrich; Kirschning, Andreas

doi:10.1002/ejoc.200400194

Cited by 127 publications

(77 citation statements)

References 99 publications

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“…Additionally, nanoconfinement of asymmetric catalysts in multiwalled carbon nanotubes was also accomplished [72,73]. Pd supported over 8 monoliths has been considered for continuous flow reactions [50,68,[74][75][76][77]. The comparison of homogeneous and heterogeneous paths for the ligandless Mizoroki-Heck reactions are also overviewed [78].…”

Section: Methodsmentioning

confidence: 99%

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Chemical reaction engineering, process design and scale-up issues at the frontier of synthesis: Flow chemistry

Rossetti

Compagnoni

2016

Chemical Engineering Journal

203

103

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Flow chemistry has been proposed in modern organic chemistry as a mean for process intensification, to improve the control over reaction performance and to achieve higher yield. However, many open issues can be evidenced regarding the true possibility of scale-up, as well as currently lacking information for process design and economical evaluation. This review proposes some recent examples of flow synthesis deepening in particular the scale-up and engineering issues. Required information is evidenced, as well as some transport and kinetic data required for the practical implementation of the results.

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Section: Methodsmentioning

confidence: 99%

“…A continuous flow microreactor was obtained from a monolithic glasspolymer composite [77]. An oxime-based palladacycle was immobilised onto polyvinylpyridine resin and it was loaded in a microreactor containing a monolithic composite material.…”

mentioning

confidence: 99%

Chemical reaction engineering, process design and scale-up issues at the frontier of synthesis: Flow chemistry

Rossetti

Compagnoni

2016

Chemical Engineering Journal

203

103

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“…[28] By taking advantage of ionic stabilization of palladium(0) particles [29] we demonstrated that these particles can be generated after reduction of palladate anions loaded on anion exchange resins [obtained by precipitation polymerization inside the void volume of megaporous glass [30] using chlormethylvinylbenzene (VBC) and divinylbenzene (DVB) as cross-linker]. [31] Beneficially, the deposition of palladium was carried out on the surface of this monolithic glass/polymer composite material inside a PASSflow reactor, a continuous flow system which was developed in our laboratories ( Figure 1). This reactor concept has the unique feature that it can be operated at a wide range of volumetric flow rates thereby reducing mass transfer phenomena.…”

Section: Introductionmentioning

confidence: 99%

Palladium(0) Nanoparticles on Glass‐Polymer Composite Materials as Recyclable Catalysts: A Comparison Study on their Use in Batch and Continuous Flow Processes

et al. 2008

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Palladium particles were generated by reduction of palladate anions bound to an ion exchange resin inside microreactors. The size and distribution of the palladium particles differed substantially depending on the degree of cross-linking and the density of ion exchange sites on the polymer/ glass composites, the latter parameter having a larger influence than the former. The polymer phase of the composite materials was used for the loading with clusters composed of palladium particles which are 1 to 10 nm in diameter. The reactivity and stability of six different palladium-doped polymer/glass composite samples for transfer hydrogenations was investigated both under conventional and microwave heating in the batch mode as well as under continuous flow conditions using the cyclohexene-promoted transfer hydrogenation of ethyl cinnamate as a model reaction. Regarding the heating method it was found that catalysts that are composed of larger metal particles perform better under microwave irradiating conditions whereas samples with smaller particle sizes perform better under conventional heating. Comparing batch experiments with flow-through experiments the latter technique gives better conversion. Reusability was better in microwave heated experiments than in traditional heating.

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“…The general procedure was modified from previous protocols for immobilising Pd within monolithic structures or on beads. [11,15,[18][19][20] The reactor system presented herein contrasts traditional polystyrene or silica solid sup-ports, which have a granular, bead or gel form, [7,[20][21][22][23][24] as it consists of multiple capillaries manufactured from ethylene-vinyl alcohol (EVOH). The capillary geometry provides a known flow profile, which can be easily characterised and modelled, and does not suffer from channelling problems that are typically observed in packed bed systems.…”

Section: Introductionmentioning

confidence: 99%

A Palladium Wall Coated Microcapillary Reactor for Use in Continuous Flow Transfer Hydrogenation

et al. 2010

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Herein we describe the preparation of a novel continuous flow multi-channel microreactor in which the internal surface has been functionalised with a palladium coating, enabling its use in catalytic heterogeneous liquid-phase reactions. Simple chemical deposition techniques were used to immobilise palladium(0) on the channel wall surface of a polymeric multi-capillary extrudate made from ethylenevinyl alcohol copolymer. The Pd coating of the microcapillaries has been characterised by mass spectrometry and light and electron microscopy. The functional activity of the catalytic Pd layer was tested in a series of transfer hydrogenation reactions using triethylsilane as the hydrogen source.

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Development of a Continuous‐Flow System for Catalysis with Palladium(0) Particles

Cited by 127 publications

References 99 publications

Chemical reaction engineering, process design and scale-up issues at the frontier of synthesis: Flow chemistry

Chemical reaction engineering, process design and scale-up issues at the frontier of synthesis: Flow chemistry

Palladium(0) Nanoparticles on Glass‐Polymer Composite Materials as Recyclable Catalysts: A Comparison Study on their Use in Batch and Continuous Flow Processes

A Palladium Wall Coated Microcapillary Reactor for Use in Continuous Flow Transfer Hydrogenation

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