Catalysis Science & Technology Blog

Homogeneous catalyst recovery made easier

23 Apr 2012

Recovering homogeneous catalysts at the end of a chemical reaction can be tricky as the catalysts are in the same phase as the products. But scientists in Canada have now found a way to do this that doesn’t suffer from the slow reaction rates that affect current catalyst recovery systems. Currently, catalyst recovery systems in use in industry rely on an aqueous/organic mixture. The catalyst is dissolved in the aqueous phase and the reagents are in the organic phase. The problem with this, though, is that because the catalyst and reagents only meet at the interface between the two, the reaction is slow.

Philip Jessop and colleagues at Queen’s University, Ontario, have come up with a solvent system that switches from a single phase for a quick reaction to two phases for quick and easy separation. The team tested their system on a homogeneous catalytic reaction. First, they carried out the reaction in a one-phase switchable water/organic solvent mix and then switched the water’s properties to get two phases – one holding the product and the other holding the catalyst. ‘Switchable water is a CO₂-switchable solvent – its physical properties can be changed by applying or removing CO₂, ‘ explains Sean Mercer from Jessop’s group.

Monophasic hydroformylation and biphasic separation in a liquid mixture of switchable water and tert-butanol

The switchable water solvent mix comprises water and a tertiary amine base, resulting in water free from salts. Introducing CO₂ leads to the formation of salts (carbonic acid forms in the water and protonates the amine base, generating charged species or salts), forcing out the organic solvent. The product, which is in the organic solvent, can then be removed, leaving behind the catalyst, which stays in the water. Removing the CO₂ by heating and flushing with air causes the charged species to revert back to their original uncharged form, making the water salt-free once more. ‘Fresh reagents and organic solvent can then be added and the reaction can be run again and again,’ says Mercer.

‘Others have done this in a slightly different way, in which the originally hydrophobic catalyst switches into water on passing CO₂, but Jessop’s “switchable water” approach has the advantage that he can use simple water soluble ligands that can be bought off the shelf, whilst the ligand switching requires specially designed ligands that are difficult to make,’ says David Cole-Hamilton, an expert in homogeneous catalysis at the University of St Andrews, UK. However, he does point out that there are still problems to be addressed, including a fall off in conversion after several cycles, which he says can almost certainly be fixed by improved reactor and recycler design and by the rigorous exclusion of air.

Another issue, adds Mercer, is that they perform the catalysis in a highly basic medium, so certain reactions can’t be performed. ‘We also need to enlarge the number of reactions that can be performed using this solvent system, as we only demonstrated the hydroformylation of alkenes to aldehydes,’ he says. ‘A second issue is we sometimes observe slight leaching of our precious metal catalyst into the organic phase so it is lost from the process. In the immediate future, we need to find catalysts that leach less, or move to less expensive metals so that losses aren’t as detrimental monetarily.’

Written by Elinor Richards

Recycling of a homogeneous catalyst using switchable water
Sean M. Mercer, Tobias Robert, Daniel V. Dixon and Philip G. Jessop
DOI: 10.1039/C2CY20095C

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Biodegradation pathway for α,β-unsaturated haloesters

20 Apr 2012

By Jennifer Newton, Publishing Editor.

Kurt Faber and colleagues from the Unviersity of Graz report the reductive dehalogenation of β-haloacrylic ester derivatives using members of the ‘Old Yellow Enzyme’ family of flavoproteins in this HOT Catalysis Science & Technology communication. They have combined the ‘reductive activity of ene-reductases with the spontaneous β-elimination of hydohalous acid from the unstable (saturated) intermediates’ in this biodegradation pathway. Such work is important for its application to the disposal of organic halogenated materials that have negative effects on the environment.

This is another fantastic article that is due to be included in our upcoming Biocatalysis themed issue. Download the communication today – it’s free…

Reductive dehalogenation of β-haloacrylic ester derivatives mediated by ene-reductases
Gábor Tasnádi, Christoph K. Winkler, Dorina Clay, Mélanie Hall and Kurt Faber
Catal. Sci. Technol., 2012
DOI: 10.1039/C2CY20079A

You might also find the group’s previous Dalton Transactions paper interesting:

Bioreduction of α-methylcinnamaldehyde derivatives: chemo-enzymatic asymmetric synthesis of Lilial™ and Helional™
Clemens Stueckler, Nicole J. Mueller, Christoph K. Winkler, Silvia M. Glueck, Karl Gruber, Georg Steinkellner and Kurt Faber
Dalton Trans., 2010, 39, 8472-8476
DOI: 10.1039/C002971H
From themed issue Bridging the gap in catalysis via multidisciplinary approaches

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Organocatalysis for optically active heteroaromatic compounds

13 Apr 2012

By Matthew Cude, Development Editor.

Heteroaromatic frameworks are valuable products with applications in a range of industries, the largest being in the pharmaceutical and drug discovery business. Developing the synthetic processes used to create these products is a growing field of research and enantioselective organocatalysis is proving to be an interesting and economic route to accomplish this.

This Perspective article from Karl Jørgensen’s group details a recently developed one-pot synthesis for constructing hydroxyalkyl- and aminoalkyl-substituted heteroaromatic compounds, these optically active products are formed in good yields with high enantioselectivities and minimal waste. Their novel methodology provides an important new route to synthesising heteroaromatic compounds for academia and industry alike.

Registration to download all articles published in Catalysis Science & Technology is free and provides access to all previously published articles in the journal – sign up here.

Organocatalytic synthesis of optically active heteroaromatic compounds
Łukasz Albrecht , Lars Krogager Ransborg and Karl Anker Jørgensen
DOI: 10.1039/C2CY20101A

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Call for Papers: Heterogeneous catalytic aerobic oxidation for the synthesis of fine chemicals

11 Apr 2012

By Matthew Cude, Development Editor.

We welcome submissions for our upcoming Themed Issue ‘Heterogeneous catalytic aerobic oxidation for the synthesis of fine chemicals’, Guest Edited by Professor Alfons Baiker and Dr Tamas Mallat.

This special issue will focus on novel aspects of aerobic oxidation such as biomass conversion, new catalyst formulations, mechanistic and kinetic studies, application of neoteric solvents such as ionic liquids and supercritical fluids, and reactor development. The scope of the Themed Issue will mainly cover heterogeneously catalyzed oxidation processes but will also include related processes based on homogeneous and biocatalysts.

Want to submit?
The Themed Issue is due to be published early 2013 and we hope to receive manuscripts by 1st July 2012, we are accepting all manuscript types including Perspective review articles, Minireviews and original research papers as communications or full papers (check our author guidelines for more details). You can submit your work as usual using our online submission system, although please indicate that you intend your paper to be included in this special themed issue.

All manuscripts will undergo the usual rigorous peer-review process to maintain the high quality of the journal and inclusion in the Themed Issue will be at the discretion of the Guest Editors.

Please don’t hesitate to contact us if you have any questions or would like any further information about this special issue.

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Biocatalysis for isotopic labelling

11 Apr 2012

By Matthew Cude, Development Editor.

Isotopic labelling is an important tool to investigate chemical processes, from discrete reactions to pharmacodynamics and biological metabolism. Replacing atoms with isotopes is an interesting area of chemistry and this Hot Communication by Matthew Truppo et al. from Merck is no exception.

The team use transaminases to create chiral amines. The method allows efficient generation of both deuterium and tritium labelled amines and is effective on several ketone substrates, potentially providing a general route to D and T labelled chiral amines for a range of applications.

Asymmetric, biocatalytic labeled compound synthesis using transaminases
Matthew Truppo, Jacob M. Janey, Brendan Grau, Krista Morley, Scott Pollack, Greg Hughes and Ian Davies

This article is due to be published in our upcoming themed issue focusing on biocatalysis, other articles to be included in this special issue include,

Mutational analysis of phenolic acid decarboxylase from Bacillus subtilis (BsPAD), which converts bio-derived phenolic acids to styrene derivatives
Annika Frank, William Eborall, Ralph Hyde, Sam Hart, Johan P. Turkenburg and Gideon Grogan

Stereoselective synthesis of bulky 1,2-diols with alcohol dehydrogenases
Justyna Kulig, Robert Christian Simon, Christopher Rose, Masood Husain, Matthias Häckh, Steffen Lüdeke, Kirsten Zeitler, Wolfgang Kroutil, M Pohl and Dörte Rother

Asymmetric reduction of a key intermediate of eslicarbazepine acetate using whole cell biotransformation in a biphasic medium
Manpreet Singh, Sawraj Singh, Sateesh Deshaboina, Hare Krishnen, Richard Lloyd, Karen Holt-Tiffin, Apurba Bhattacharya and Rakeshwar Bandichhor
C2CY00537A

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Shining light on the Hantzsch reaction

10 Apr 2012

By Fiona McKenzie, Executive Editor.

This article is HOT as recommended by the referees

Scientists from the Indian Institute of Technology have investigated the effect of visible light on the Hantzsch reaction – a method by which to produce dihydropyridines which have found merit for cardiovascular disease treatment. By doing so, they were able to develop a photocatalytic-based methodology for producing 2-arylpyridines. Whilst such compounds are popular in medicinal chemistry and supramolecular coordination chemistry fields, their synthesis can be troublesome.

Armed with a catalytic amount of [Ru(bpy)₃]²⁺ and a household compact fluorescent lamp, the team synthesised the 2-arylpyridine compound through photocatalytic oxidation of the 1,2-dihydropyridine Hantzsch product.

For further details on the reaction conditions and mechanism, read the the Full Paper:
[Ru(bpy)₃]²⁺ Aided Photocatalytic Synthesis of 2-Arylpyridines via Hantzsch Reaction under the Visible Irradiation and Oxygen Atmosphere
Rajakumar Ananthakrishnan and Sarifuddin Gazi

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Register now for Free Access

30 Mar 2012

By Matthew Cude, Development Editor.

Catalysis Science & Technology – A multidisciplinary journal focussing on all fundamental science and technological aspects of catalysis

Next month will see Catalysis Science & Technology reach its first anniversary, meaning we are more than half way through our free access period!

At the end of this year the journal will no longer be free to access, so make sure you make the most of this free period and sign up to free access by clicking on the big pink button on our journal homepage. Alternatively just click below and we’ll redirect you to the registration page.

Remember you can also keep up to date with the latest news and developments in all things catalysis by following us on twitter, liking us on facebook and signing up to e-alerts.

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Heterogenising tungsten POMs for epoxidation catalysis

30 Mar 2012

By Fiona McKenzie, Executive Editor.

Tungsten-based polyoxometalates have been identified as ideal catalysts for epoxidation of alkenes, particularly since the corresponding reaction utilises H₂O₂ as the oxidant where only water is produced as the by-product. In order for this catalytic approach to be useful for industrial scale-up, the catalyst must be able to be separated from the products and recycled – heterogeneous catalysis being one route to achieve this.

In their recent HOT Catalysis Science & Technology article, Jean-Marc Clacens and his team describe how the tungsten POMs can be encapsulated within mesoporous silica (SBA-15) to effect the epoxidation of styrene and methyl oleate in solvent-free conditions. By grafting octyl groups onto the surface at the pore entrances, they ensured that the POM species did not leach from the silica, enabling re-use of the catalyst.

Clacen’s method is sure to inspire further research for developing green syntheses of such synthetically valuable epoxide molecules.

Download the article now for free now…
Catalytic epoxidation of styrene and methyl oleate over peroxophosphotungstate entrapped in mesoporous SBA-15
Evelyne Poli, Rodolphe De Sousa, François Jérome, Yannick Pouilloux and Jean-Marc Clacens

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Borderline catalyst has best of both worlds

28 Mar 2012

By Fiona McKenzie, Executive Editor.

Heterogeneous catalysts in the powerful Suzuki–Miyaura reaction for forming C–C bonds are still struggling to rival homogeneous ones in terms of catalytic activity, despite being more reusable and easier to recover. But now, scientists from China have made an inorganic-supported palladium catalyst that is soluble in organic solvent for the first time.

The homogenised zirconium phosphate supported catalysts can be used at room temperature and removed from the reaction mixture using solid/liquid separation.

By bridging the shortcomings of both heterogeneous and homogeneous catalysts, the team have produced a borderline class of catalyst, which can easily be extended to other metal systems.

Read the Catalysis Science & Technology article now…
Homogenization of inorganic material-supported palladium catalysts in Suzuki coupling reaction at room temperature
Yueyue Ma, Xuebing Ma, Qiang Wang and Jinqin Zhou

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Catalysis Science & Technology Blog

Top ten most accessed articles in March

Homogeneous catalyst recovery made easier

Biodegradation pathway for α,β-unsaturated haloesters

Organocatalysis for optically active heteroaromatic compounds

Call for Papers: Heterogeneous catalytic aerobic oxidation for the synthesis of fine chemicals

Biocatalysis for isotopic labelling

Shining light on the Hantzsch reaction

Register now for Free Access

Heterogenising tungsten POMs for epoxidation catalysis

Borderline catalyst has best of both worlds

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