Archive for the ‘News’ Category

A year of water splitting from one device

 Abigail Hallowes writes about an EES article in Chemistry World


Researchers from the US have optimised a photoelectrochemical cell (PEC) so that it can continuously split water into clean burning hydrogen and oxygen for over 2200 hours – the equivalent to one year of outdoor operation.

In order for PECs to be a competitive energy provider, they should efficiently covert solar into chemical energy, whilst remaining stable for years of continuous operation. The condition of the electrodes in PECs is a major concern as they immediately start to corrode once immersed in the electrolyte. Previous PEC researchers have only been able to produce systems that are either stable for 4–100 hours but inefficient, or efficient but only stable for a few minutes; they have not been able to incorporate both required properties.

Scanning-electron micrograph image of a microwire array with its protective coating

Scanning-electron micrograph image of a microwire array with its protective coating

 
Electrode instability is brought on when the energy required to excite an electron is within the same energy range that causes electrode corrosion; photocorrosion then becomes competitive with water splitting. In these cases, it is most likely that photocorrosion is thermodynamically more favourable which therefore leads to unstable electrodes. Now, a team led by Nathan Lewis at the California Institute of Technology have drastically increased PEC stability whilst achieving a 100% Faradaic efficiency for oxygen evolution.
 
Their approach increased the electrochemically active sites versus the surface area of the electrode through the use of silicon microwire arrays; this led to a decrease in the effective current density at the electrode–electrolyte interface, increasing the energy required for photocorrosion, which decreased the rate of photocorrosion. They also coated the arrays in a protective but conductive layer, to act as a corrosion-resistant barrier while maintaining efficient charge transfer to the reaction sites, as well as with an oxygen evolution catalyst to promote water oxidation.
 
Brian Seger, a photoelectrochemist at the Technical University of Denmark, explains that water splitting provides some very corrosive conditions so stability has been a large hurdle in this field: ‘The fact that the Lewis group could test their device for three months with no noticeable corrosion indicates that this hurdle is surmountable.’
 
Materials scientist, Dongyuan Zhao, of Fudan University, China, describes the work was a breakthrough and says it ‘shows great potential for industrial application.’

Interested to find out more? Read the full article by Abigail Hallowes in Chemistry World.

Read the original article in Energy and Environmental Science:

Stabilization of Si microwire arrays for solar-driven H2O oxidation to O2(g) in 1.0 M KOH(aq) using conformal coatings of amorphous TiO2
Matthew R. Shaner,ab   Shu Hu,ab   Ke Sunab and   Nathan S. Lewis
Energy Environ. Sci., 2015, Advance Article
DOI: 10.1039/C4EE03012E

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Redirecting electrons boosts algal hydrogen generation

Scientists in Germany have developed a highly targeted metabolic engineering technique to control the flow of electrons produced by the initial stages of photosynthesis in microalgae, and used it to increase hydrogen production by a factor of The hydrogen yield from green algae like Chlamydomonas reinhardtii is normally restricted by physiological constraints © AMI Images/Science Photo Libraryfive.

Hydrogen is increasingly being touted as an environmentally friendly alternative to conventional fossil fuels, but, ‘at present, hydrogen is mainly produced from natural gas, which makes it a “wolf in sheep’s clothing”,’ comments Oliver Inderwildi, a senior policy fellow at the Smith School of Enterprise and the Environment, University of Oxford, UK. Natural microalgae produce hydrogen by harnessing energy from sunlight, but their low production rate limits their practical application. Organisms typically use most of the electrons they generate to make the carbohydrates they need to live.

Previous studies in this area had focussed on curbing carbohydrate production. Now, Wolfgang Lubitz, of the Max Planck Institute for Chemical Energy Conversion, and co-workers have modified a ferredoxin protein responsible for distributing photo-generated electrons in the green algae Chlamydomonas reinhardtii with the aim of boosting its hydrogen output, whilst allowing the organism to be self-sustaining.

Interested to find out more? Read the full article by Jonathan Midgley in Chemistry World.

Read the original article in Energy & Environmental Science:

Enhancing hydrogen production of microalgae by redirecting electrons from photosystem I to hydrogenase
Sigrun Rumpel, Judith F. Siebel, Christophe Farès, Jifu Duan, Edward Reijerse, Thomas Happe, Wolfgang Lubitz and Martin Winkler
Energy Environ. Sci., 2014, Advance Article
DOI: 10.1039/C4EE01444H

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Spray-deposition steers perovskite solar cells towards commercialisation

A low-cost, high-efficiency technique for fabricating perovskite solar cells – ultra-sonic spray-coating – has been Spray-coated perovskite solar cells © Lucy Pickforddeveloped by a team of researchers in the UK. It represents a significant step towards commercialising perovskite solar cells.

David Lidzey, head of the research group at the University of Sheffield behind the study, explains that there has been ‘interest in developing solar cell materials that are easy to process, efficient and have less embodied energy than current technologies.’

Thin-film solar cells using perovskite semi-conductors have become a promising form of photovoltaic device achieving power conversion efficiencies of up to 15–19%, surpassing the efficiencies of amorphous silicon and organic semi-conductor photovoltaics.

Perovskite films can be fabricated by depositing precursor materials from solution. However, there have been few reports detailing the application of scalable solution-processing techniques to create these films.

In this study, an ultra-sonic spray-coating of methylamine iodide and lead chloride created a thin film of a perovskite precursor under ambient conditions. The film was then thermally annealed into a CH3NH3PbI3–ᵪClᵪ perovskite structure prior to inclusion within a solar cell with a planar heterojunction architecture.

Interested to find out more? Read the full article by Vicki Marshall in Chemistry World.

Read the original article in Energy and Environmental Science:

Efficient planar heterojunction mixed-halide perovskite solar cells deposited via spray-deposition
Alexander T. Barrows, Andrew J. Pearson, Chan Kyu Kwak, Alan D. F. Dunbar, Alastair R. Buckley and David G. Lidzey
Energy Environ. Sci., 2014, Advance Article
DOI: 10.1039/C4EE01546K 

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Organic solar cells reach manufacturing milestone

In an impressive feat of engineering, scientists in Denmark have devised a rapid, scalable and industrially viable way to manufacture large sheets of flexible organic tandem solar cells. Their successful application of roll-to-roll processing is a significant achievement for this emerging renewable technology.Organic solar cells reach manufacturing milestone

An organic photovoltaic (OPV) solar cell is a polymer-based thin film solar cell. OPV solar cells have been the focus of much research as they are lightweight, flexible, inexpensive, highly tuneable and potentially disposable. They are also unparalleled in the number of times that they can pay back the energy used in their manufacture.

In the quest to improve the efficiency of OPVs, which, in addition to operational lifetime, is currently their key limitation, various new materials, processing methods and device architectures have been investigated. Among these is the tandem cell, where multiple junctions are stacked upon one another. This can increase the efficiency of the cell by not only increasing the number of junctions, but, along with careful selection of complimentary materials, can make it possible to harvest photons from a broader region of the spectrum. However, this more complicated architecture renders their manufacture significantly more challenging.

Interested to find out more? Read the full article by William Bergius in Chemistry World.

Read the original article in Energy and Environmental Science:

Scalable, ambient atmosphere roll-to-roll manufacture of encapsulated large area, flexible organic tandem solar cell modules
Energy Environ. Sci., 2014, Advance Article
DOI: 10.1039/C4EE01223B
Thomas R. Andersen, Henrik F. Dam, Markus Hösel, Martin Helgesen, Jon E. Carlé, Thue T. Larsen-Olsen, Suren A. Gevorgyan, Jens W. Andreasen, Jens Adams, Ning Li et al.

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EES Lectureship Award at Clean Energy Conference

Presentation of EES readers choice lectureship

Winner of the 2013 EES Readers Choice Award Lecture Prof. Tom Jaramillo, and EES Deputy Editor Dr Heather Montgomery

Qingdao, China was the location for the lively and informative 2nd International Conference on Clean Energy Science (ICCES2), with lectures from key figures from around the world.

Energy & Environmental Science were delighted to present Professor Tom Jaramillo with the Energy & Environmental Science Readers’ Choice Lectureship Award at the event, and Prof. Jaramillo’s talk presenting insights on how to design a sustainable and efficient catalyst for CO2 reduction was very well received.

Prof. Jaramillo was awarded the lectureship for his EES article “New insights into the electrochemical reduction of carbon dioxide on metallic copper surfaces” which was one of the most downloaded articles in 2013.

To keep up to date with the latest published articles in Energy & Environmental Science, and our news and related events, sign up to our EES e-alerts and news service: http://www.rsc.org/Publishing/Journals/forms/V5profile.asp.

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EES Issue 4 of 2014 out now!

Graphical abstract: Front coverThe latest issue of EES is now online. You can read the full issue here.

The outside front cover features the paper Binary additives synergistically boost the efficiency of all-polymer solar cells up to 3.45% by Pei Cheng, Long Ye, Xingang Zhao, Jianhui Hou, Yongfang Li and Xiaowei Zhan.

Coupling surface plasmon resonance of gold nanoparticles with slow-photon-effect of TiO2 photonic crystals for synergistically enhanced photoelectrochemical water splitting is the paper highlighted on the inside front cover by Xing Zhang, Yang Liu, Shuit-Tong Lee, Shihe Yang and Zhenhui Kang.

Issue 4 contains a number of excellent Editorial, Review, and Perspective articles:

Two stories from the ISACS 12 conference: solar-fuel devices and catalyst identification
Zhuangqun Huang, Chengxiang Xiang, Hans-Joachim Lewerenz and Nathan S. Lewis

Recent progress on nitrogen/carbon structures designed for use in energy and sustainability applications
Kevin N. Wood, Ryan O’Hayre and Svitlana Pylypenko

Energy storage applications of activated carbons: supercapacitors and hydrogen storage
Marta Sevilla and Robert Mokaya Graphical abstract: Inside front cover

Recent advances in multifunctional nanocarbons used in dye-sensitized solar cells
Rubén D. Costa, Fabian Lodermeyer, Rubén Casillas and Dirk M. Guldi

Graphene oxide derivatives as hole- and electron-extraction layers for high-performance polymer solar cells
Jun Liu, Michael Durstock and Liming Dai

Progress in flexible lithium batteries and future prospects
Guangmin Zhou, Feng Li and Hui-Ming Cheng

A perspective on the high-voltage LiMn1.5Ni0.5O4 spinel cathode for lithium-ion batteries
Arumugam Manthiram, Katharine Chemelewski and Eun-Sung Lee

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Egg-white derived activated carbons display an eggs-tremely high pseudocapacitance in asymmetric supercapacitors

Scientists in Canada have employed a novel template-free approach to prepare so-called Highly Functionalized Activated Carbons (HFACs) derived from common chicken egg-whites. When employed as the anode in an aqueous asymmetric supercapacitor, the materials display a colossal pseudocapacitance of > 550 F g-1, and double the specific energy in comparison to standard activated carbon.

Supercapacitors are energy-storage devices which, unlike batteries, have the phenomenal ability to charge and discharge within a matter of seconds. This makes them useful for high-power applications such as regenerative breaking in electric vehicles, but their low specific energy (energy per unit mass) limits their use in other applications where batteries are preferred.

Conventional supercapacitors typically employ activated carbon (AC) as both the positive and negative electrodes, and are therefore regarded as symmetric. Asymmetric supercapacitors on the other hand often replace the positive electrode with a nanostructured metal oxide – and, in doing so, can show an improved capacitance and energy density.

In their recent paper, David Mitlin and co-workers found that nitrogen-rich Highly Functionalized Activated Carbons (HFACs) – derived from chicken egg-whites – displayed a colossal pseudocapacitance of > 550 F g-1 when employed as an anode in an aqueous asymmetric supercapacitor system, and had double the specific energy in comparison to standard activated carbon.  This performance rivals that of other state-of-the-art carbons, despite the simple template-free approach and abundance and renewable nature of egg-white precursors.

Find out more about their egg-citing work in their full article:

Colossal pseudocapacitance in a high functionality–high surface area carbon anode doubles the energy of an asymmetric supercapacitor
Zhi Li, Zhanwei Xu, Huanlei Wang, Jia Ding, Beniamin Zahiri, Chris M. B. Holt, Xuehai Tanab and David Mitlin
Energy Environ. Sci., 2014, Advance Article
DOI: 10.1039/c3ee43979h

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EES Issue 3 of 2014 out now!

Graphical abstract: Front coverThe latest issue of EES is now online. You can read the full issue here.

The outside front cover features the paper Optical designs that improve the efficiency of Cu2ZnSn(S,Se)4 solar cells by Mark T. Winkler, Wei Wang, Oki Gunawan, Harold J. Hovel, Teodor K. Todorov and David B. Mitzi.

Visible light driven photocatalysis mediated via ligand-to-metal charge transfer (LMCT): an alternative approach to solar activation of titania is the paper highlighted on the inside front cover by Guan Zhang, Gonu Kim and Wonyong Choi.

Issue 3 contains a number of excellent Opinion, Analysis, Review, and Perspective articles:

Solar energy: setting the economic bar from the top-down
E. W. McFarland

Large scale deployment of polymer solar cells on land, on sea and in the air
Nieves Espinosa, Markus Hösel, Mikkel Jørgensen and Frederik C. Krebs

Capacitive energy storage in micro-scale devices: recent advances in design and fabrication of micro-supercapacitors
Majid Beidaghi and Yury Gogotsi

Spin caloritronics
Stephen R. Boona, Roberto C. Myers and Joseph P. HeremansGraphical abstract: Inside front cover

Towards sustainable wastewater treatment by using microbial fuel cells-centered technologies
Wen-Wei Li, Han-Qing Yu and Zhen He

From lab to fab: how must the polymer solar cell materials design change? – an industrial perspective
Riccardo Po, Andrea Bernardi, Anna Calabrese, Chiara Carbonera, Gianni Corso and Andrea Pellegrino

Interfacial reactions in ceramic membrane reactors for syngas production
A. S. Yu, J. M. Vohs and R. J. Gorte

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Revealing electron transfer in current-producing bacteria

Researchers from Japan and the USA have found the first clue to the electron transfer mechanism in a species of current-producing bacteria.

Some bacteria can generate electrical energy from its metabolic systems, and they are used in microbial fuel cells and bioremediation processes. Geobacter sulfurreducens is the most efficient current-producing bacteria found so far, but there is no conclusive mechanism for electron transfer from the bacteria to the electrode.

In this paper, Ryuhei Nakamura et al. the authors identify self-secreted flavin as the electron shuttle involved in this extracellular electron transfer (EET). For this bacteria, free-floating flavin in the solution does not contribute to EET, as changing the solution to a fresh one did not impact current production. Instead, electron transfer occurs through flavin bound to c-type cytochromes (c-Cyts) on the outer membrane.

The authors confirmed flavin secretion by spectroscopy and mass chromatography, and voltammetry showed that current production was influenced by the amount of flavin present. The importance of c-Cyts was revealed by a mutant comparison experiment, in which a mutant lacking several major c-Cyts produced less current than the wild type.

Extracellular electron transfer (EET) is a key step in current production from bacteria, and understanding the mechanisms involved can lead to optimization of microbial fuel cells.

by Bhavin Siritanaratkul

For more information read this Energy & Environmental Science article:

Uptake of self-secreted flavins as bound cofactors for extracellular electron transfer in Geobacter species
Akihiro Okamoto, Koichiro Saito, Kengo Inoue, Kenneth H. Nealson, Kazuhito Hashimoto and Ryuhei Nakamura
DOI: 10.1039/C3EE43674H

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Multi-shelled hematite microspheres: high-performance anode materials for the Li-ion battery

Researchers from the University of Science and Technology Beijing, China, have developed a novel technique for the fabrication of multi-shelled α-Fe2O3 microspheres. The spheres, when tested as anode materials for Li-ion batteries (LIB), give ultra-high specific capacity values of up to 1702 mAhg-1, which is about 5 times higher than that of graphite (372 mAhg-1) – the currently employed material for LIB anodes.

The performance of the current generation of LIBs is fundamentally limited by the properties of their material components. The charge stored per gram, or specific capacity, of the anode is one such limiting factor; with graphite restricted to a maximum capacity of 372 mAhg-1. Numerous other materials are capable of exceeding this value, however they typically suffer from poor rechargeability (or cycle stability) owing to the fact they expand/contract considerably upon charge/discharge cycling – which causes the electrodes to crumble.

One such material is α-Fe2O3, or hematite, which, as well as being low-cost, abundant and non-toxic, has a high theoretical capacity of 1000 mAhg-1, however it suffers from a destructive volume change of about 90 % upon cycling. A group led by Dan Wang has managed to overcome this problem by preparing α-Fe2O3 as hollow, thin-shelled, concentric microspheres, which are capable of buffering the mechanical stresses upon cycling and therefore prevent crumbling.

In their paper, they reported stable reversible capacities as high as 1702 mAhg-1, which is record-breaking performance for additive-free α-Fe2O3 – and even beats the maximum theoretical capacity of 1000 mAhg-1. What’s more, the materials also display excellent high-current performance; maintaining a high capacity of about 1100 mAhg-1 at a current rate of 1 Ag-1. The authors attributed this excellent performance to the novel concentric shell structure of the hollow microspheres, which is capable of buffering mechanical stresses whilst providing a high surface area for rapid Li-ion transfer kinetics.

So could Dan Wong’s α-Fe2O3 spheres the next big thing for Li-ion batteries? He-matite just be on to something…

Interested? Read the full article here:

α-Fe2O3 multi-shelled hollow microspheres for lithium ion battery anodes with superior capacity and charge retention

Simeng Xu, Colin M. Hessel, Hao Ren, Ranbo Yu, Quan Jin, Mei Yang, Huijun Zhao and Dan Wang
Energy Environ. Sci., 2014, Advance Article
DOI: 10.1039/C3EE43319F

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