Archive for February, 2011

Bendy batteries a step closer…

Scientists from Korea have found that with the use of graphene nanosheets, the fabrication of bendable power sources is possible.

Electronic devices are no longer confined to the home or office. We travel with them, carry them around and even wear them. To make equipment like roll-up displays and wearable devices achievable, the power source that supplies them must also become more flexible.

The major challenge of developing a truly bendable power source has been the shortage of material that is both highly flexible and has superior electronic conductivity. Polymers are typically used, but they can degrade at relatively low temperatures, which makes them less than ideal.

Kisuk Kang from the Korea Advanced Institute of Science and Technology in Daejon, and colleagues, have developed a graphene based hybrid electrode producing a flexible lithium rechargeable battery. The cathode material, in this case V2O5, is grown on graphene paper using pulsed laser deposition and graphene paper coated in lithium is used as the anode. The resultant battery is lightweight and flexible enough to be twisted or rolled.

Bendy batteries a step closer

Want to find out more?

Read the rest of the Chemistry World story by Rebecca Brodie

Or view the Energy & Environmental Science article in full:
Flexible energy storage devices based on graphene paper
Hyeokjo Gwon, Hyun-Suk Kim, Kye Ung Lee, Dong-Hwa Seo, Yun Chang Park, Yun-Sung Lee, Byung Tae Ahn and Kisuk Kang,
Energy Environ. Sci.
, 2011, DOI: 10.1039/c0ee00640h

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

The latest top ten most downloaded Energy & Environmental Science articles

See the most-read papers of January 2011 here:

Mark Z. Jacobson, Energy Environ. Sci., 2009, 2, 148-173
DOI: 10.1039/B809990C
 
Tayebeh Ameri, Gilles Dennler, Christoph Lungenschmied and Christoph J. Brabec, Energy Environ. Sci., 2009, 2, 347-363
DOI: 10.1039/B817952B
 
A. J. Minnich, M. S. Dresselhaus, Z. F. Ren and G. Chen, Energy Environ. Sci., 2009, 2, 466-479
DOI: 10.1039/B822664B
 
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
 
Irene Gonzalez-Valls and Monica Lira-Cantu, Energy Environ. Sci., 2009, 2, 19-34
DOI: 10.1039/B811536B
 
María D. Hernández-Alonso, Fernando Fresno, Silvia Suárez and Juan M. Coronado, Energy Environ. Sci., 2009, 2, 1231-1257
DOI: 10.1039/B907933E
 
Roberto Rinaldi and Ferdi Schüth, Energy Environ. Sci., 2009, 2, 610-626
DOI: 10.1039/B902668A
 
V. Thavasi, G. Singh and S. Ramakrishna, Energy Environ. Sci., 2008, 1, 205-221
DOI: 10.1039/B809074M
 
Venkata Pradeep Indrakanti, James D. Kubicki and Harold H. Schobert, Energy Environ. Sci., 2009, 2, 745-758
DOI: 10.1039/B822176F
 
Yunfei Zhou, Michael Eck and Michael Krüger, Energy Environ. Sci., 2010, 3, 1851-1864
DOI: 10.1039/C0EE00143K

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Fuel cells: taking inspiration from rocket fuel…

HOT’ Minireview – hot off the press…

Carbon-free energyReviewing recent advances in ammonia and hydrazine based electrochemical fuel cells

Most low-temperature fuel cells are based, in some form, on the hydrogen fuel cell, due to its high power density and clean oxidation to yield no carbon-containing products. However, due to issues of compression and storage, research has been on-going into alternative “hydrogen-storage” compounds that can deliver similar performance in a more convenient form.

The nitrogen hydrides, ammonia and hydrazine, have been candidate materials for fuels for nearly 50 years, but rapid advances in the past 5–6 years have shown them to be front-runners in the race for commercial, high-performance, portable fuel cells.

Carbon-free energy: a review of ammonia- and hydrazine-based electrochemical fuel cells
Neil V. Rees and Richard G. Compton
Energy Environ. Sci., 2011, DOI: 10.1039/C0EE00809E

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Artificial photosynthesis – ‘HOT’ feature article

‘HOT’ Energy & Environmental Science Perspective article

Is there a catalysts that can make artificial photosynthesis a reality?

Artificial photosynthetic systemsThis review covers the progress achieved in the synthesis and characterization of different metal based catalysts designed for the photocatalytic oxidation of water, with special focus on molecular designed systems.

Artificial photosynthetic systems: Using light and water to provide electrons and protons for the synthesis of a fuel
Christian Herrero, Annamaria Quaranta, Winfried Leibl, A. William Rutherford and Ally Aukauloo
Energy Environ. Sci., 2011, DOI: 10.1039/C0EE00645A

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Fabulous functionalised fibres for fuel cells

A remarkable new electrode design represents a significant leap in microbial fuel cell (MFC) technology. Fuel cells using the new cathode have more than two times the power density of current commercially available cathodes.

SEM image of the surface of the CNT–textile composite

The porous textile fibre network is critical for cathode performance

MFCs are a promising technology that is able to act as both a renewable energy source and wastewater treatment method. They use the catalytic activity of microbes to oxidise organic matter in wastewater using oxygen, generating electrical energy. However, fuel cell performance is often limited by the cathode performance.

Continuing work previously published, the researchers have developed a new aqueous electrode (i.e. designed to work when submerged in an electrolyte purged with oxygen) in which they deposit platinum nanoparticles onto a carbon nanotube–textile composite.

The electrode allows a maximum MFC power density of 837 mW m−2; using a commercial carbon cloth–Pt electrode only obtains a density of 391 mW m−2.

This enhanced performance is attributed to the cathode’s superior design:

  • the network of textile fibres allows a much larger electrochemically active surface area;
  • the network also contains macroscale pores for fast access of electrolyte;
  • a glacial acetic acid treatment during synthesis provided the electrode with an hydrophilic surface.

Read more about this exciting new work now:

Nano-structured textiles as high-performance aqueous cathodes for microbial fuel cells
Xing Xie, Mauro Pasta, Liangbing Hu, Yuan Yang, James McDonough, Judy Cha, Craig S. Criddle and Yi Cui
Energy Environ. Sci., 2011, Advance Article, DOI: 10.1039/C0EE00793E

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Breakthrough for bacterial hydrogen production

Breakthrough for bacterial hydrogen production

by Philippa Ross

Scientists in China have developed a device that can produce hydrogen from organic materials using bacteria at temperatures below 25 degrees Celsius.

Normally, hydrogen production by bacterial metabolism is reduced at lower temperatures because it slows down the enzymes that catalyse the reactions. Now, Defeng Xing and his team at the Harbin Institute of Technology have optimised hydrogen production from organic matter between 4 and 9 degrees Celsius by using a microbial electrolysis cell (MEC). This eliminates the cost of heating and could enable hydrogen production to be carried out at high latitudes and mountainous regions where the air temperature is below 10 degrees Celsius.

MECs generate hydrogen directly upon applying an electric current to bacteria. Bacteria consume acetic acid, which is produced from fermenting plant matter and release protons, electrons and CO2. Addition of an electric current enables the protons and electrons to join together to make hydrogen gas and the higher the current, the more hydrogen is produced.

Breakthrough for bacterial hydrogen production

‘In order to achieve a high yield of hydrogen in MECs, it’s essential that both the electron transfer and hydrogen recovery processes are highly efficient,’ explains Xing.

Methanogenesis, or methane formation, is a common problem in MECs, which occurs at higher temperatures as a result of bacterial anaerobic respiration. This can reduce the efficiency of electron transfer to the cathode, reducing the overall output of hydrogen. However, at temperatures below 10 degrees Celsius, no methane was produced since the growth of the methane producing organisms was inhibited and the yield of hydrogen produced is comparable to that at temperatures above 25 degrees Celsius.

Sarah  Strycharz-Glaven, an expert in microbial fuel cells at the Naval Research Laboratory in Washington DC is impressed with the group’s findings but acknowledges that there is some progress to be made. ‘The authors will need to increase the efficiency of hydrogen production under colder conditions to compete with MECs operating at ambient conditions,’ she says.

The group aim to do this by increasing hydrogen recovery and exploring new electrode materials. In the future they hope that MEC technology could be considered for biohydrogen production in cold environments.

Read the Energy & Environmental Science article now:

Hydrogen production, methanogen inhibition and microbial community structures in psychrophilic single-chamber microbial electrolysis cells
Lu Lu, Nanqi Ren, Xin Zhao, Huan Wang, Di Wu and Defeng Xing
Energy Environ. Sci., 2011, Advance Article, DOI: 10.1039/C0EE00588F

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Could urea be the future source of hydrogen?

Energy & Environmental Science Perspective

This ‘HOT’ feature article reviews the potential of urea ((NH2)2CO) as a hydrogen carrier for fuel cells and the feasibility of utilising the enormous natural resource of urea that already exists.

Urea is a cheap and readily available resource, and has the advantage over other chemicals of being non-toxic and stable, and therefore easy to transport and store.

The authors say that urea “could be a solution to long-term future sustainable hydrogen supply” and conclude that urea is a realistic sustainable route and could be exploited if sufficient research is undertaken.

Read this ‘HOT’ Perspective today:
Urea as a hydrogen carrier: a perspective on its potential for safe, sustainable and long-term energy supply

Andrew N. Rollinson, Jenny Jones, Valerie Dupont and Martyn V. Twigg
Energy Environ. Sci., 2011, DOI: 10.1039/C0EE00705F

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The true cost of getting energy from the sun

US scientists have proposed a new method to compare the cost of solar energy technology with traditional sources as current methods may not give a realistic result

Seth Darling and colleagues from the Argonne National Laboratory in Illinois have used a simulation that gives distributions of values for variable parameters such as weather, solar panel performance, operating costs and inflation to more accurately reflect the overall cost.

‘For solar energy to make a significant dent in the overall energy mix, its cost will have to be similar to or lower than traditional sources such as fossil fuels,’ says Darling, ‘but to make this comparison, you need to know how to calculate the cost.’

Monte Carlo simulation

The results indicate that the real discount rate is the most relevant factor,‘ says José Goldemberg, an expert on energy and environmental issues from the University of São Paulo, Brazil.

Darling hopes that stakeholders in the energy community will adopt his approach. The biggest challenge, he says, is getting performance data from diverse geographic locations. 

‘We hope that partnerships between the solar energy industry, utility providers and national laboratories will focus on collecting the data and making it accessible to those interested in exploring the potential of solar energy,’ he concludes.

Read more of the Chemistry World feature here

View the Energy Environmental Science Analysis article:

Assumptions and the levelized cost of energy for photovoltaics
Seth B. Darling, Fengqi You, Thomas Veselka and Alfonso Velosa
Energy Environ. Sci., 2011, DOI: 10.1039/c0ee00698j

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A simple and efficient way to reduce CO2

With increasing concerns over global warming and the urgent need to reduce CO2 emissions, scientists in China have developed a new simple and efficient strategy for the reduction of CO2.

They demonstrate a carbon cycle which is driven simply by the oxidation and reduction of commonly available metals, such as iron.

The cycle begins with the high-yield reduction of CO2 to formic, via the oxidation of a zero-valent metal under hydrothermal conditions. The metal oxide can then be converted back to the metal using a bio-derived chemical such as glycerin, which is readily available from renewable resources.

reduce co2

The production of formic acid in the cycle is also an added bonus, as this can be used to power fuel cells, which can be applied to small, portable electronics such as cell phones and laptop computers.

This new energy system has many advantages over current methods to reduce CO2 (such as water-splitting) as it has high yields, no waste products, does not require expensive catalysts or harsh reagents and, as the overall cycle is exothermic, it is expected to have minimal energy requirements.

Read the ‘HOT’ Communication today:

High-yield reduction of carbon dioxide into formic acid by zero-valent metal/metal oxide redox cycles
Fangming Jin, Ying Gao, Yujia Jin, Yalei Zhang, Jianglin Cao, Zhen Wei and Richard L. Smith Jr
Energy Environ. Sci., 2011, DOI: 10.1039/C0EE00661K

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EES paper featured on Green Car Congress website

An Energy & Environmental Science paper has been highlighted on the Green Car Congress website.

The work by Hugh O’Neill and colleagues at the Oak Ridge National Laboratory demonstrates a novel approach for developing a new class of smart materials with architectures that are dependent on the assembly of interacting components. These could have important implications in self-repair and control of energy transfer in photoconversion devices.

Read the Energy & Environmental Science paper today:

Supramolecular assembly of biohybrid photoconversion systems
Mateus B. Cardoso, Dmitriy Smolensky, William T. Heller, Kunlun Hong and Hugh O’Neill
Energy Environ. Sci., 2011, 4, 181-188
DOI: 10.1039/C0EE00369G

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