Your search keyword '"Zor C"' showing total 2 results

1. H 2 -Driven biocatalytic hydrogenation in continuous flow using enzyme-modified carbon nanotube columns.

Author

Zor C, Reeve HA, Quinson J, Thompson LA, Lonsdale TH, Dillon F, Grobert N, and Vincent KA

Subjects

Amination, Hydrogen chemistry, Hydrogenation, Ketones chemistry, Ketones metabolism, Oxidation-Reduction, Biocatalysis, Enzymes, Immobilized metabolism, Hydrogen metabolism, Hydrogenase metabolism, Nanotubes, Carbon chemistry, Oxidoreductases metabolism

Abstract

We describe the implementation of a system of immobilised enzymes for H 2 -driven NADH recycling coupled to a selective biotransformation to enable H 2 -driven biocatalysis in flow. This approach represents a platform that can be optimised for a wide range of hydrogenation steps and is shown here for enantioselective ketone reduction and reductive amination.

Published

2017

2. Dedicated carbon scaffolds for next generation hydrogenation chemistry and H2 evolution

Author

Zor, C, Grobert, N, Vincent, K, and Dillon, F

Subjects

Hydrogenation Chemistry, Biocatalysis, Nanostructured materials, Hydrogen Economy

Abstract

This Thesis is primarily concerned with developing sustainable and cost-efficient methods for applications of hydrogen (H2-driven fine chemical synthesis) and production of hydrogen (hydrogen evolution reaction, HER). Using novel catalysts, immobilising these catalysts, and translating the conventional batch processes to flow processes are the key solutions used for both of these processes. In the first part of this work enzymes are employed as catalysts in fine chemical synthesis. Enzymes are enantio-, regio- and stereoselective, can be used in mild reaction conditions, and can be easily produced in the laboratory. It is possible to electronically couple a hydrogenase to an NAD+ reductase enzyme via conductive carbon particles for NAD+ to NADH reduction. Thus, enzymes were immobilised on high surface area, porous and electronically conducting commercial carbon particles for H2-driven generation of NADH, an expensive cofactor required by many enzymes to work, in batch. The commercial carbon materials which are conventionally used for metal catalysed hydrogenation reactions were shown to be suitable supports for enzymes used in H2-driven biotransformations in batch. In this work, novel carbon nanotube columns (CNCs) were utilised as enzyme supports and flow devices for a range of H2-driven biotransformations including ketone reduction and reductive amination reactions. This is the first demonstration of H2-driven NADH recycling for selective biotransformations in flow. The second part of this work focuses on HER catalysis. Here, novel WS2 assemblies were developed as alternatives to expensive and rare platinum catalysts. WS2 nanostructures were directly grown on multi-wall carbon nanotube (MWCNT) carpets and CNCs for the first time. Preliminary electrochemical studies showed that these assemblies are suitable to be used as HER catalysts, although they require a significant overpotential. This is a promising proof-of-concept demonstration of WS2-MWCNT assemblies being used in HER catalysis. A possible future extension of this work would involve using these assemblies in flow.

Published

2017