V
Volker Hessel
Researcher at University of Adelaide
Publications - 616
Citations - 24861
Volker Hessel is an academic researcher from University of Adelaide. The author has contributed to research in topics: Microreactor & Catalysis. The author has an hindex of 68, co-authored 572 publications receiving 21707 citations. Previous affiliations of Volker Hessel include Mainz Institute of Microtechnology & Fraunhofer Society.
Papers
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Journal ArticleDOI
Lipase-Based Biocatalytic Flow Process in a Packed-Bed Microreactor
TL;DR: Novozym 435 showed to be stable up to 80 °C in the packed-bed microreactor, with low reactant molar ratio (ethyl butyrate:1-butanol) being desirable to achieve higher conversions.
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Visible Light Photocatalytic Metal-Free Perfluoroalkylation of Heteroarenes in Continuous Flow
Natan J. W. Straathof,Dannie J. G. P. van Osch,Arian Schouten,Xiao Wang,JC Jaap Schouten,Volker Hessel,Timoth Noël +6 more
TL;DR: In this article, a visible light photocatalytic metal-free perfluoroalkylation method for the functionalization of heteroarenes in continuous flow was developed.
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Fluidic bus system for chemical process engineering in the laboratory and for small-scale production
Andreas Müller,V. Cominos,Volker Hessel,B. Horn,Jochen Schürer,Athanassios Ziogas,K. Jähnisch,V. Hillmann,V. Großer,K. A. Jam,Alexis Bazzanella,G. Rinke,M. Kraut +12 more
TL;DR: In this paper, five research institutes are developing a standardized system for the combination of microstructured devices and laboratory equipment of various suppliers, thus leading to the building of chemical plants.
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Liquid-liquid extraction for the separation of Co(II) from Ni(II) with Cyanex 272 using a pilot scale Re-entrance flow microreactor
TL;DR: In this paper, a 3D conical micro-reactor was used for continuous re-entrance flow in selective extraction of Co from Ni sulfate solution with Cyanex 272.
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Intensification of the Capillary-Based Kolbe−Schmitt Synthesis from Resorcinol by Reactive Ionic Liquids, Microwave Heating, or a Combination Thereof
TL;DR: In this paper, the power-to-temperature graphs were calibrated with water and real-case (ion-containing) solutions, revealing several features relevant for process control, including the process intensification potential of microwave irradiation for heating up the reactant solution and/or of using ionic liquids as carbonating reactants.