A Sustainable Global Society – a new international white paper published

The annual Chemical Sciences and Society Summit (CS3) brings together the best minds in chemical research from around the world and challenges them to propose innovative solutions for society’s most pressing needs in the areas of health, food, energy, and the environment.

The focus of this year’s summit was on sustainable materials; thirty top materials chemists from the five participating countries assembled in London to identify the scientific research required to address key global challenges, and to provide recommendations to policy makers.

CS3Read the The Sustainable Global Society Report today to find out more.

The CS3 initiative is a collaboration between the:

  • Chinese Chemical Society (CCS)
  • German Chemical Society (GDCh)
  • Chemical Society of Japan (CSJ)
  • Royal Society of Chemistry (RSC)
  • American Chemical Society (ACS)

The symposia are supported by the:

  • National Science Foundation of China (NSFC)
  • German Research Foundation (DFG)
  • Japan Society for the Promotion of Science (JSPS)
  • UK Engineering and Physical Sciences Research Council (EPSRC)
  • US National Science Foundation (NSF)

Find out more about Chemical Sciences and Society Summit (CS3)

Read the The Sustainable Global Society Report

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Top Ten most-read Energy & Environmental Science articles in February

The latest top ten most downloaded Energy & Environmental Science articles

See the most-read papers of February 2011 here:

Yiqing Sun, Qiong Wu and Gaoquan Shi, Energy Environ. Sci., 2011, Advance Article
DOI: 10.1039/C0EE00683A
 
Seth B. Darling, Fengqi You, Thomas Veselka and Alfonso Velosa, Energy Environ. Sci., 2011, Advance Article
DOI: 10.1039/C0EE00698J
 
Energy Environ. Sci., 2011, 4, 604-604
DOI: 10.1039/C1EE90001C
 
Brian J. Landi, Matthew J. Ganter, Cory D. Cress, Roberta A. DiLeo and Ryne P. Raffaelle, Energy Environ. Sci., 2009, 2, 638-654
DOI: 10.1039/B904116H
 
Jun Liu, Thomas E. Conry, Xiangyun Song, Marca M. Doeff and Thomas J. Richardson, Energy Environ. Sci., 2011, 4, 885-888
DOI: 10.1039/C0EE00662A
 
Dongsheng Geng, Ying Chen, Yougui Chen, Yongliang Li, Ruying Li, Xueliang Sun, Siyu Ye and Shanna Knights, Energy Environ. Sci., 2011, 4, 760-764
DOI: 10.1039/C0EE00326C
 
Hun-Gi Jung, Seung-Taek Myung, Chong Seung Yoon, Seoung-Bum Son, Kyu Hwan Oh, Khalil Amine, Bruno Scrosati and Yang-Kook Sun, Energy Environ. Sci., 2011, Advance Article
DOI: 10.1039/C0EE00620C
 
Seung Woo Lee, Betar M. Gallant, Hye Ryung Byon, Paula T. Hammond and Yang Shao-Horn, Energy Environ. Sci., 2011, Advance Article
DOI: 10.1039/C0EE00642D
 
Riccardo Po, Chiara Carbonera, Andrea Bernardi and Nadia Camaioni, Energy Environ. Sci., 2011, 4, 285-310
DOI: 10.1039/C0EE00273A
 
María D. Hernández-Alonso, Fernando Fresno, Silvia Suárez and Juan M. Coronado, Energy Environ. Sci., 2009, 2, 1231-1257
DOI: 10.1039/B907933E

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A simple way to get fresh drinking water

Scientists in the US have developed a membrane-free, solvent extraction method to remove salt from seawater that works at low temperatures.

Access to clean, fresh water is a necessity. Unfortunately, supply is becoming over-stretched and there is a struggle to meet demand. As a result, the development of desalination technology (the conversion of salt water to fresh water) has become increasingly important.

Current desalination techniques require large amounts of energy or membranes that need to be changed constantly as they become blocked. Although significant advances have been made in these areas, Gang Chen and colleagues from the Massachusetts Institute of Technology, Cambridge, have gone a step further and removed the need for a membrane entirely.

Simple salt removal to get fresh water

The team used decanoic acid as a solvent to mix with the water. ‘Upon slight heating, our solvent dissolves the water out, leaving salts and impurities behind. Then, upon cooling, the mixture separates into two layers by gravity, releasing pure water. Unlike reverse osmosis, this method does not use expensive membranes and unlike evaporation processes, does not need heating to high temperatures,’ explains Chen. The process was shown to be effective at temperatures as low as 40 degrees Celsius and the recovered water met the salinity standards set by the World Health Organisation and the US Environmental Protection Agency.

Adel Sharif, an expert in water engineering and director of the Centre for Osmosis Research and Applications at the University of Surrey, UK, believes that further research is needed in areas such as scalability and practicality, but believes that the concept has promise. ‘The proposed desalination process has the potential for low environmental impact, since it uses low grade heat, and for low capital and operating costs,’ he says.

Chen believes that the work opens up a new field of research in desalination. ‘Being a simple, inexpensive process, directional solvent extraction also bears tremendous commercial potential in the desalination of seawater, clean-up of industrial waste water, treatment of water produced from oil and gas wells and other such uses,’ he concludes.

Rebecca Brodie

Read the Energy & Environmental Science article in full:

Very low temperature membrane-free desalination by directional solvent extraction
Anurag Bajpayee, Tengfei Luo, Andrew Muto and Gang Chen
Energy Environ. Sci., 2011, DOI: 10.1039/c1ee01027a

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Carbon capture using sawdust

Plants may help to reduce carbon dioxide in the atmosphere when dead as well as alive, say scientists from Spain.

Carbon capture – the removal of CO2 from waste gases (such as from power plants) – is an important method for reducing CO2 emissions. One such strategy is the use of porous solids, such as zeolites and porous carbons, to absorb CO2 into their pores. However, these materials exhibit poor uptake capacities (about 3mmol CO2/g) and have complex and costly syntheses.

Now, Antonio Fuertes and his group at the National Institute of Carbon, Oviedo, have made a porous carbon material that performs better than other currently available ones, using a simple and inexpensive process. The major difference in this work, however, is that the raw material is sawdust.

The two step synthesis involves hydrothermal carbonisation of the sawdust, creating a hydrochar, which is then activated using potassium hydroxide. The KOH treatment creates pores in the sawdust structure by oxidation of carbon and carbon gasification from K2CO3 decomposition. These pores are responsible for the material’s uptake capabilities, bestowing it with a capacity as high as 4.8mmol CO2/g. In addition, Fuertes’ material has good selectivity for CO2 over N2, fast adsorption rates and can be easily regenerated.

Carbon capture with sawdust

Magnified image of sawdust before (left) and after (right) being heated and activated, showing the pores

This type of carbonaceous material gives rise to an activated carbon that possesses textural properties that are appropriate for CO2 capture,’ says Fuertes. ‘What’s more, the fabrication process is not complex and the raw material is abundant and widely available.’

Peter Styring, an expert in carbon capture technologies at the University of Sheffield says that the material has advantages over the currently most popular class of materials. ‘They’re comparable in terms of performance [to alkanolamines], but in terms of their engineering capabilities, these are superior,’ he explains. ‘With the alkanolamines, you get problems with corrosion, evaporation and degradation.’

Fuertes says that there is more work to be done before this technology can be commercialised, including investigations into scaling up. For now, he is focusing on other materials, such as nitrogen-doped carbons.

Yuandi Li

Read the Energy & Environmental Science article:
Sustainable porous carbons with a superior performance for CO2 capture

Marta Sevilla and Antonio B. Fuertes
Energy Environ. Sci., 2011, DOI: 10.1039/c0ee00784f

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Cool roof coating inspired by the poplar leaf

Scientists in China have made a reflective coating with a structure that mimics the underside of a poplar tree leaf. The coating could be used on the outside of buildings to counteract the heating effect of carbon dioxide emissions, reducing the energy needed to cool the building from the inside.

Yanlin Song and colleagues from the Chinese Academy of Sciences, Beijing, mimicked the structure of the leaf’s lower surface using polymers spun into reflective films consisting of long, hollow uniform fibres.

The underside of the poplar leaf is better at reflecting light than the top. This is because of the ‘cool roof’ effect, in which a layer of hairs on the underside reflects the light, so that less heat penetrates the leaf. The leaf turns over in strong sunlight to reveal the underside and as the light is being reflected rather than absorbed, the leaf appears white. ‘Normally, the poplar tree looks green, but sometimes in the summer, the tree shows a white cast,’ says Song.

Cool roof coating inspired by the poplar leaf

The poplar leaf's hair structure (left) and the reflective coating with a magnified image showing one of the hollow fibres (right)

The team discovered that controlling the film thickness and making the cross section of the fibres as similar to the leaf hair as possible is the key to high reflectivity. They tested their films by coating them onto the compound diarylethene, which changes from red to colourless in the presence of visible light – the structure changes from a closed ring to an open ring. They found that the coating stopped the diarylethene changing colour, and had the additional benefit of being hydrophobic.

‘The reflectance and waterproof nature of the coatings make them ideal candidates for a number of building situations,’ says Robert Lamb, an expert on surface science. ‘Improving the durability of such delicate interfaces with the environment will be the major hurdle, but the alternative of sticking poplar leaves to our roofs to achieve the same effect is really not an option!’

Song says that his team will continue to develop highly reflective materials, widening the wavelength at which they function, to eventually be used to improve the efficiency of lighting.

Holly Sheahan

Read the journal article in full:

Highly reflective superhydrophobic white coating inspired by poplar leaf hairs toward an effective cool roof
Changqing Ye, Mingzhu Li, Junping Hu, Qunfeng Cheng, Lei Jiang and Yanlin Song
Energy Environ. Sci., 2011, DOI: 10.1039/c0ee00686f

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Cleaning up nuclear storage ponds

UK scientists have analysed the chemistry taking place in storage ponds at nuclear power sites, such as Sellafield, to come up with a way to remove radioactive waste as nuclear regulatory bodies are pressing on the nuclear industry to clean up the ponds.

Storage ponds are used to store spent Magnox rods, which are uranium fuel rods covered by a magnesium-aluminium alloy cladding. The rods contain large amounts of fission products, which are highly reactive. The ponds are maintained to minimise corrosion of the rods, but the cladding corrodes in water, creating fine particle sludge. ‘The sludge in one of these ponds is estimated to contain tonnes of fuel debris including considerable quantities of plutonium,’ says Stephen Parry from the University of Manchester.

Parry, together with his colleagues, made a model of Magnox storage pond liquor to study how plutonium interacts with the corroded Magnox sludge to find a way of removing the plutonium before the ponds are emptied.

Cleaning up nuclear storage ponds

A magnified image of nuclear storage pond sludge showing brucite crystals, which sequester plutonium, making it difficult to remove from the mixture

One potential problem is the risk that disturbing the sludge will release fine, plutonium-containing particles in the effluent from the ponds. Pond effluents are treated before discharge into the sea under authorisation, but we need to be sure that the treatment process will effectively remove plutonium from the effluents before we can start to empty them,‘ explains Parry.

The team found that a low carbonate concentration, high CMS concentration and high polyelectrolyte concentration resulted in almost all of the plutonium being filtered.

Read the rest of the Chemistry World article…

Or view the Energy & Environmental Science paper:

Plutonium behaviour in nuclear fuel storage pond effluents
Stephen A. Parry, Luke O’Brien, Andy S. Fellerman, Christopher J. Eaves, Neil B. Milestone, Nicholas D. Bryan and Francis R. Livens
Energy Environ. Sci.
, 2011, DOI: 10.1039/c0ee00390e

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Carbon nanostructures: high-profile collection

Energy & Environmental Science is delighted to present the current issue as a high-profile themed issue on Carbon nanostructures, Guest Edited by Professor Nazario Martin, Professor Dirk M. Guldi and Professor Andreas Hirsch.

coverIt showcases some of the great current research in this very significant research area, featuring a collection of Perspectives, Minireviews, short Communications and full papers.

Take a look today!

Minireview
Graphene-based nanomaterials for energy storage
Martin Pumera, Energy Environ. Sci., 2011, 4, 668

Perspective
Underneath the fascinations of carbon nanotubes and graphene nanoribbons
Wei-Tao Zheng and Chang Q Sun, Energy Environ. Sci., 2011, 4, 627

HOT paper
Efficient light harvesting anionic heptamethine cyanine–[60] and [70]fullerene hybrids
Carmen Villegas, Evangelos Krokos, Pierre-Antoine Bouit, Juan Luis Delgado, Dirk M. Guldi and Nazario Martín, Energy Environ. Sci., 2011, 4, 679

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Hydrocarbon proton conducting polymers for fuel cell catalyst layers

HOT Review – proton conducting, hydrocarbon polymers in fuel cell catalyst layers

PEMFCProton exchange membrane fuel cells (PEMFCs) employing proton conducting membranes are promising power sources for automotive applications.

Perfluorosulfonic acid (PFSA) ionomer represents the state-of-the-art polymer used in both the membrane and catalyst layer to facilitate the transport of protons. However, PFSA ionomer is recognized as having significant drawbacks for large-scale commercialization.

This review highlights the role of the solid polymer electrolyte in catalyst layers on pertinent parameters associated with fuel cell performance, and focuses on the effect of replacing perfluorosulfonic acid ionomer with hydrocarbon polyelectrolytes. Collectively, this review aims to provide a better understanding of factors that have hindered the transition from PFSA to non-PFSA based catalyst layers.

Read the Energy & Environmental Science paper in full:

Hydrocarbon proton conducting polymers for fuel cell catalyst layers
Jennifer Peron, Zhiqing Shi and Steven Holdcroft
Energy Environ. Sci., 2011, DOI: 10.1039/C0EE00638F

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Drawing batteries

Scientists in Japan have made an electrode for a lithium-air battery using a pencil. The advance could bring efficient, environmentally friendly and safe batteries for electric vehicles a step closer.

Lithium-air batteries have the potential to produce enough energy to power an electric vehicle, but the amount of energy is a safety concern. Contamination in lithium batteries can result in unstable and high energy reactions, and the current lithium-air batteries are vulnerable to decomposition and burn-out.

Drawing batteries

Haoshen Zhou and Yonggang Wang at the National Institute of Advanced Industrial Science and Technology in Tsukuba, have designed a battery in which the lithium is encapsulated by an organic electrolyte topped with a ceramic protection layer. The ceramic layer acts as a solid-state electrolyte upon which the team simply drew a 2D cathode using a graphite pencil. Zhou says that ‘removing and redrawing the novel air electrode is simple.’

Read the Chemistry World article by Harriet Brewerton in full

Or read the Energy & Environmental Science paper

To draw an air electrode of a Li–air battery by pencil
Yonggang Wang and Haoshen Zhou,
Energy Environ. Sci., 2011, DOI: 10.1039/c0ee00759e

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Sweetening gas – without thermal heating

‘HOT’ paper – Chemically Selective Gas Sweetening Without Thermal-Swing Regeneration

Scientists have reacted anhydrous alkanolamines with H2S to produce switchable hydrosulfide-based ionic liquids, of which H2S can be released without thermal heating. H2S removal from natural gas is commonly known as ‘‘gas sweetening,’’ a process that uses either physical or chemical sorbents.

Read the Energy & Environmental Science article today – hot off the press!

Chemically Selective Gas Sweetening Without Thermal-Swing Regeneration
P K Koech, J E Rainbolt, M D Bearden, F Zheng and D J Heldebrant
Energy Environ. Sci., 2011, DOI: 10.1039/ c0ee00839g

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