Author Archive

Outstanding organocatalysis: An article collection

Catalysts are key to some of the most important reactions on the planet; a world without the Haber process or catalysts to crack crude oil is difficult to imagine. Not to mention the enzymatic reactions that are crucial to all life on earth.

Organocatalysts are an important class of catalyst and consist of carbon-based molecules often functionalised with oxygen, sulfur, nitrogen or phosphorus. They have shown promise in a range of reactions including hydrogenation, Diels-Alder, Michael and Mannich reactions, and are of particular interest in asymmetric reactions.

To help keep you up-to-date with the latest in cutting-edge organocatalytic research we have made the following articles free to access until the 9th July. After reading all these there will be little you won’t know about the exciting world of organocatalysis!

Click here for the full list of free articles

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Multi-functional catalysts and the Fischer–Tropsch synthesis

Multi-functional catalysts have huge potential; they can run simultaneous or consecutive reactions and facilitate complicated multi-reaction processes. The Fischer–Tropsch synthesis converts carbon monoxide and hydrogen into hydrocarbons, an interesting gas to liquid process which is ever more relevant with growing energy demands.

catalyst heterogeneous hydrocarbon ZSM-5 energy catalysis science technology sustainable fuel

The catalyst shows excellent selectivity for the gasoline fraction hydrocarbons

This Hot Communication from Baoning Zong and colleagues details an interesting bifunctional Raney Fe/H-ZSM-5 catalyst which shows good selectivity and is very effective at converting the gases into gasoline-range hydrocarbons. The chemical structuring of the catalyst is key to its success – download the article below for more details.

A highly selective Raney Fe@HZSM-5 Fischer–Tropsch synthesis catalyst for gasoline production: one-pot synthesis and unexpected effect of zeolites
Bo Sun, Guobin Yu, Jun Lin, Ke Xu, Yan Pei, Shirun Yan, Minghua Qiao, Kangnian Fan, Xiaoxin Zhang and Baoning Zong

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Biodiesel, a fuel for the future….but what about the waste?

Reusability of catalysts

The topic of sustainable energy needs no introduction and while there are numerous technologies that provide a more sustainable and environmentally friendly energy source, no single process has been identified as the best way forward. This is in part due to the fact that current supplies of energy, whether generated by gas, coal, nuclear, solar, wind or tidal sources, all have their own disadvantages.

Biodiesel is no different, as the transesterification of readily available vegetable oils produces large quantities of waste glycerol as a by-product (around 10 wt%) causing substantial economic waste.

In their manuscript Binbin Zhao, Chengcheng Li and Chunli Xu discuss their attempts to understand the conversion of glycerol into the more useful product 1,2-propanediol. The reaction mechanism of glycerol hydrogenolysis is not well understood so the team have tried to study it using a Cu/Mg-Al mixed-oxide catalyst with hydrotalcite-like compounds (a class of anionic clays found in nature).

Mechanism of glycerol hydrogenolysis on reconstructed hydrotalcite

You can download the manuscript below for full details of the team’s research

Insight of catalytic mechanism of glycerol hydrogenolysis using basal spacing of hydrotalcite as a tool
Binbin Zhao, Chengcheng Li and Chunli Xu
Journal Article
Catal. Sci. Technol., 2012, Accepted Manuscript
DOI: 10.1039/C2CY20144E

If you’re interested in finding out more information about the role of catalysis in sustainable energy you can take a look at our previous blog post The quest for cleaner, cheaper, more sustainable energy.

Of course you can keep up to date with the latest news in catalysis hassle free, by following us on twitter, liking us on facebook, or signing up to our e-alerts!

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Zeal for zeolites: an article collection

ZeoliteZeolites are truly fascinating materials, first noted in the 18th century they were recognized for their interesting ability to release steam when heated. Today around 3 million tons of natural zeolite are mined for commercial use each year. Zeolites have found applications in agriculture, construction, heating, refrigeration, nuclear energy, in the petrochemical industry, as detergents and cat litter!

Unsurprisingly these materials have sparked the interest of scientists around the world since their discovery, resulting in the creation of a vast number of unique zeolitic frameworks and pushing the boundaries of chemical understanding.

The articles below have been made free to access until 8th June to give you a sample of the high impact, cutting edge research being carried out in the exciting world of zeolites!

Click here for the full list of free articles

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A Fine Catalyst for Success: Sicily

finecat2012

Professor Graham Hutchings speaking on the latest developments using supported gold and gold palladium nanoparticles as heterogeneous catalysts

By Mario Pagliaro  and Leonardo Palmisano

The first “FineCat – Symposium on heterogeneous catalysis for fine chemicals” was held in Palermo, Italy, on April 18-19, 2012 in the splendid venue of the Steri Palace, hall of Palermo’s University Rectorate.

The idea for this meeting was born out of the 2011 themed issue of Catalysis Science & Technology, Heterogeneous catalysis for fine chemicals (dedicated to Professor Michele Rossi), and took less than 3 months to go from idea to reality.

The scientific programme featured 14 symposia and 5 poster presentations, with the best poster winning the acclaimed Catalysis Science & Technology certificate and a copy of Enantioselective Homogeneous Supported Catalysis. The lectures and posters highlighted exciting chemical innovation from theoretical through practical approaches including predicting catalyst performance, gold catalysis for selective oxidations, asymmetric syntheses and hybrid silicates, bio-hydrogen production and photocatalysis for organic synthesis.

Younger and more experienced scientists at the Symposium were chosen in a good balance to present and discuss advances in the field, whereas eminent chemists Graham Hutchings from Cardiff University and Gadi Rothenberg from the University of Amsterdam were invited to give the plenary lectures.

On April 18th, Professor Rothenberg opened the conference with a lecture on a simple, but effective, new method for predicting catalyst performance….

Read the full conference report

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Homogeneous catalyst recovery made easier

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

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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Organocatalysis for optically active heteroaromatic compounds

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.

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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

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.

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

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.

Transaminase reaction

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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Register now for Free Access

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.

Click here to sign up for free access

 

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.

Sign up for free access now!

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