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Integrated artificial photosynthesis nanosystem, a first for Lawrence Berkeley National Laboratory

Friday, May 17th, 2013

There’s such a thing as too much information and not enough knowledge, a condition I’m currently suffering from with regard to artificial photosynthesis. Before expanding on that theme, here’s the latest about artificial photosynthesis from a May 16, 2013 Lawrence Berkeley National Laboratory news release (also available on EurekAlert),

In the wake of the sobering news that atmospheric carbon dioxide is now at its highest level in at least three million years, an important advance in the race to develop carbon-neutral renewable energy sources has been achieved. Scientists with the U.S. Department of Energy (DOE)’s Lawrence Berkeley National Laboratory (Berkeley Lab) have reported the first fully integrated nanosystem for artificial photosynthesis. While “artificial leaf” is the popular term for such a system, the key to this success was an “artificial forest.”

Here’s a more detailed description of the system, from the news release,

“Similar to the chloroplasts in green plants that carry out photosynthesis, our artificial photosynthetic system is composed of two semiconductor light absorbers, an interfacial layer for charge transport, and spatially separated co-catalysts,” says Peidong Yang, a chemist with Berkeley Lab’s Materials Sciences Division, who led this research. “To facilitate solar water- splitting in our system, we synthesized tree-like nanowire  heterostructures, consisting of silicon trunks and titanium oxide branches. Visually, arrays of these nanostructures very much resemble an artificial forest.”

… Artificial photosynthesis, in which solar energy is directly converted into chemical fuels, is regarded as one of the most promising of solar technologies. A major challenge for artificial photosynthesis is to produce hydrogen cheaply enough to compete with fossil fuels. Meeting this challenge requires an integrated system that can efficiently absorb sunlight and produce charge-carriers to drive separate water reduction and oxidation half-reactions.

More specifically,

“In natural photosynthesis the energy of absorbed sunlight produces energized charge-carriers that execute chemical reactions in separate regions of the chloroplast,” Yang says. “We’ve integrated our nanowire nanoscale heterostructure into a functional system that mimics the integration in chloroplasts and provides a conceptual blueprint for better solar-to-fuel conversion efficiencies in the future.”

When sunlight is absorbed by pigment molecules in a chloroplast, an energized electron is generated that moves from molecule to molecule through a transport chain until ultimately it drives the conversion of carbon dioxide into carbohydrate sugars. This electron transport chain is called a “Z-scheme” because the pattern of movement resembles the letter Z on its side. Yang and his colleagues also use a Z-scheme in their system only they deploy two Earth abundant and stable semiconductors – silicon and titanium oxide – loaded with co-catalysts and with an ohmic contact inserted between them. Silicon was used for the hydrogen-generating photocathode and titanium oxide for the oxygen-generating photoanode. The tree-like architecture was used to maximize the system’s performance. Like trees in a real forest, the dense arrays of artificial nanowire trees suppress sunlight reflection and provide more surface area for fuel producing reactions.

“Upon illumination photo-excited electron−hole pairs are generated in silicon and titanium oxide, which absorb different regions of the solar spectrum,” Yang says. “The photo-generated electrons in the silicon nanowires migrate to the surface and reduce protons to generate hydrogen while the photo-generated holes in the titanium oxide nanowires oxidize water to evolve  oxygen molecules. The majority charge carriers from both semiconductors recombine at the ohmic contact, completing the relay of the Z-scheme, similar to that of natural photosynthesis.”

Under simulated sunlight, this integrated nanowire-based artificial photosynthesis system achieved a 0.12-percent solar-to-fuel conversion efficiency. Although comparable to some natural photosynthetic conversion efficiencies, this rate will have to be substantially improved for commercial use. [emphasis mine] However, the modular design of this system allows for newly discovered individual components to be readily incorporated to improve its performance. For example, Yang notes that the photocurrent output from the system’s silicon cathodes and titanium oxide anodes do not match, and that the lower photocurrent output from the anodes is limiting the system’s overall performance.

“We have some good ideas to develop stable photoanodes with better performance than titanium oxide,” Yang says. “We’re confident that we will be able to replace titanium oxide anodes in the near future and push the energy conversion efficiency up into single digit percentages.”

Now I can discuss my confusion, which stems from my May 24, 2013 posting about work done at the Argonne National Laboratory,

… Researchers still have a long way to go before they will be able to create devices that match the light harvesting efficiency of a plant.

One reason for this shortcoming, Tiede [Argonne biochemist David Tiede] explained, is that artificial photosynthesis experiments have not been able to replicate the molecular matrix that contains the chromophores. “The level that we are at with artificial photosynthesis is that we can make the pigments and stick them together, but we cannot duplicate any of the external environment,” he said.  “The next step is to build in this framework, and then these kinds of quantum effects may become more apparent.”

Because the moment when the quantum effect occurs is so short-lived – less than a trillionth of a second – scientists will have a hard time ascertaining biological and physical rationales for their existence in the first place. [emphasis mine]

It’s not clear to me whether or not the folks at the Berkeley Lab bypassed the ‘problem’ described by Tiede or solved it to achieve solar-to-fuel conversion rates comparable to natural photosynthesis conversions. As I noted, too much information/not enough knowledge.

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Canadian federal government coughs up funds ($1.8M) for ecoEnergy project at the University of Waterloo Institute for Nanotechnology

Tuesday, May 14th, 2013

Stephen Harper, Prime Minister of  Canada, recently announced a series of 32 grants for Natural Resources Canada’s ecoENERGY Innovation Initiative. From the May 3, 2013 announcement,

To this end, on May 3, 2013, Prime Minister Stephen Harper announced support of more than $82 million through Natural Resources Canada’s ecoENERGY Innovation Initiative (ecoEII) for 55 innovative projects across Canada. Of these, 15 will be pre-commercialization demonstration projects to test the feasibility of various technologies, and 40 will be research and development projects to address knowledge gaps and bring technologies from the conceptual stage to the ready-to-be-tested stage of development.

For all projects, funding provided by NRCan will be allocated from the date of signature of contribution agreements until March 31, 2016, the project end date.

Since 2006, the Government of Canada has taken action to reduce greenhouse gas emissions and build a more sustainable environment through more than $10 billion in investments in green infrastructure, energy efficiency, clean energy technologies and the production of cleaner energy and cleaner fuels.

….

High Energy Density Energy Storage for Automotive Applications
Lead Proponent: University of Waterloo
Location: Waterloo, Ontario
Funding: $1,870,000

Today’s electric vehicles are limited by driving range and cost, both of which greatly depend on the electric vehicle’s battery pack. The objective of this project is to develop advanced energy materials based on nanotechnology concepts for high energy density storage.

There’s more about the announcement in a May 14, 2013 news item in the LabCanada.com Daily news,

Led by Professor Linda Nazar of the Faculty of Science and the Waterloo Institute for Nanotechnology at the University of Waterloo, the study will examine completely new approaches to materials and chemical components of batteries that could result in more powerful, and longer-lasting batteries for hybrid electric or electric cars.

“The funding from Natural Resources Canada allows us to expand our electrochemical energy storage laboratory here at Waterloo to explore beyond lithium-ion batteries using nanotechnology and completely different approaches to battery chemistry,” said Professor Nazar, a Canada Research Chair in Solid State Energy Materials. “This research is high-risk, but it has the potential to create batteries with much greater storage capacity and at lower costs.”

Natural Resources Canada (NRCan) is providing $1.8 million over four years to Professor Nazar for her work titled High Energy Density Storage for Automotive Applications.  Partnerships on the project include Hydro-Québec, the Korea Institute of Energy Technology Evaluation and Planning, and BASF (SE).

For anyone who’s interested in Natural Resources Canada’s ecoENERGY Innovation Initiative (ecoEII), here’s the website.

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Bringing home the chilling effects of outer space

Tuesday, April 16th, 2013

They’ve invented a new type of cooling structure at Stanford University (California) which reflects sunlight back into outer space. From the Apr. 16, 2013 news item on Azonano,

A team of researchers at Stanford has designed an entirely new form of cooling structure that cools even when the sun is shining. Such a structure could vastly improve the daylight cooling of buildings, cars and other structures by reflecting sunlight back into the chilly vacuum of space.

The Apr. 15, 2013 Stanford Report by Andrew Myers, which originated the news item, describes the problem the engineers were solving,

The trick, from an engineering standpoint, is twofold. First, the reflector has to reflect as much of the sunlight as possible. Poor reflectors absorb too much sunlight, heating up in the process and defeating the goal of cooling.

The second challenge is that the structure must efficiently radiate heat (from a building, for example) back into space. Thus, the structure must emit thermal radiation very efficiently within a specific wavelength range in which the atmosphere is nearly transparent. Outside this range, the thermal radiation interacts with Earth’s atmosphere. Most people are familiar with this phenomenon. It’s better known as the greenhouse effect – the cause of global climate change.

Here’s the approach they used,

Radiative cooling at nighttime has been studied extensively as a mitigation strategy for climate change, yet peak demand for cooling occurs in the daytime.

“No one had yet been able to surmount the challenges of daytime radiative cooling –of cooling when the sun is shining,” said Eden Rephaeli, a doctoral candidate in Fan’s [Shanhui Fan, a professor of electrical engineering and the paper's senior author] lab and a co-first-author of the paper. “It’s a big hurdle.”

The Stanford team has succeeded where others have come up short by turning to nanostructured photonic materials. These materials can be engineered to enhance or suppress light reflection in certain wavelengths.

“We’ve taken a very different approach compared to previous efforts in this field,” said Aaswath Raman, a doctoral candidate in Fan’s lab and a co-first-author of the paper. “We combine the thermal emitter and solar reflector into one device, making it both higher performance and much more robust and practically relevant. In particular, we’re very excited because this design makes viable both industrial-scale and off-grid applications.”

Using engineered nanophotonic materials, the team was able to strongly suppress how much heat-inducing sunlight the panel absorbs, while it radiates heat very efficiently in the key frequency range necessary to escape Earth’s atmosphere. The material is made of quartz and silicon carbide, both very weak absorbers of sunlight.

This new approach offers both economic and social benefits,

The new device is capable of achieving a net cooling power in excess of 100 watts per square meter. By comparison, today’s standard 10-percent-efficient solar panels generate about the same amount of power. That means Fan’s radiative cooling panels could theoretically be substituted on rooftops where existing solar panels feed electricity to air conditioning systems needed to cool the building.

To put it a different way, a typical one-story, single-family house with just 10 percent of its roof covered by radiative cooling panels could offset 35 percent its entire air conditioning needs during the hottest hours of the summer.

Radiative cooling has another profound advantage over other cooling equipment, such as air conditioners. It is a passive technology. It requires no energy. It has no moving parts. It is easy to maintain. You put it on the roof or the sides of buildings and it starts working immediately.

Beyond the commercial implications, Fan and his collaborators foresee a broad potential social impact. Much of the human population on Earth lives in sun-drenched regions huddled around the equator. Electrical demand to drive air conditioners is skyrocketing in these places, presenting an economic and environmental challenge. These areas tend to be poor and the power necessary to drive cooling usually means fossil-fuel power plants that compound the greenhouse gas problem.

“In addition to these regions, we can foresee applications for radiative cooling in off-the-grid areas of the developing world where air conditioning is not even possible at this time. There are large numbers of people who could benefit from such systems,” Fan said.

Here’s a citation and a link for the paper,

Ultrabroadband Photonic Structures To Achieve High-Performance Daytime Radiative Cooling by Eden Rephaeli, Aaswath Raman, and Shanhui Fan.  Nano Lett. [American Chemical Society Nano Letters], 2013, 13 (4), pp 1457–1461
DOI: 10.1021/nl4004283 Publication Date (Web): March 5, 2013
Copyright © 2013 American Chemical Society

The article is behind a paywall.

For anyone who might be interested in what constitutes hot temperatures, here’s a sampling from the Wikipedia List of weather records (Note: I have removed links and included only countries which experienced temperatures of 43.9 °C or 111 °F or more; I made one exception: Antarctica),

Temperature

Location

Date

North America / On Earth

 56.7 °C (134 °F) Furnace Creek Ranch (formerly Greenland Ranch), in Death Valley, California, United States 1913-07-10

Canada

 45.0 °C (113 °F) Midale, Yellow Grass, Saskatchewan 1937-07-05

Mexico

 52 °C (125.6 °F) San Luis Rio Colorado, Sonora

Africa

 55.0 °C (131 °F) Kebili, Tunisia 1931-07-07

Algeria

 50.6 °C (123.1 °F) In Salah, Tamanrasset Province 2002-07-12

Benin

 44.5 °C (112 °F) Kandi  ?

Burkina Faso

 47.2 °C (117 °F) Dori  ?

Cameroon

 47.7 °C (117.9 °F) Kousseri  ?

Central African Republic

 45 °C (113 °F) Birao  ?

Chad

 47.6 °C (117.7 °F) Faya-Largeau 2010-06-22

Djibouti

 49.5 °C (121 °F) Tadjourah  ?

Egypt

 50.3 °C (122.6 °F) Kharga  ?

Eritrea

 48 °C (118.4 °F) Massawa  ?

Ethiopia

 48.9 °C (120 °F) Dallol  ?

The Gambia

 45.5 °C (114 °F) Basse Santa Su 2008-?-?

Ghana

 43.9 °C (111 °F) Navrongo  ?

Libya

 50.2 °C (122.4 °F) Zuara 1995-06

Malawi

 45 °C (113 °F) Ngabu, Chikwana  ?

Mali

 48.2 °C (118 °F) Gao  ?

Mauritania

 50.0 °C (122 °F) Akujit  ?

Morocco

 49.6 °C (121.3 °F) Marrakech 2012-07-17

Mozambique

 47.3 °C (117.2 °F) Chibuto 2009-02-03

Namibia

 47.8 °C (118 °F) Noordoewer 2009-02-06

Niger

 48.2 °C (118.8 °F) Bilma 2010-06-23

Nigeria

 46.4 °C (115.5 °F) Yola 2010-04-03

Somalia

 47.8 °C (118 °F) Berbera  ?

South Africa

 50.0 °C (122 °F) Dunbrody, Eastern Cape 1918

Sudan

 49.7 °C (121.5 °F) Dongola 2010-06-25

Swaziland

 46.1 °C (115 °F) Sidvokodvo  ?

Zimbabwe

 45.6 °C (114 °F) Beitbridge,  ?

Asia

 53.6 °C (128.5 °F) Sulaibya, Kuwait 2012-07-31

Bangladesh

 45.1 °C (113.2 °F) Rajshahi 1972-04-30

China

 49.7 °C (118 °F) Ading Lake, Turpan, Xinjiang, China 2008-08-03

India

 50 °C (122 °F) Sri, Ganganagar, Rajasthan Dholpur, Rajasthan  ?

Iraq

 52.0 °C (125.7 °F) Basra, Ali Air Base, Nasiriyah 2010-06-14
2011-08-02

Israel

 53 °C (127.4 °F) Tirat Zvi, Israel 1942-06-21

Myanmar

 47.0 °C (116.6 °F) Myinmu 2010-05-12

Pakistan

 53.5 °C (128.3 °F) Mohenjo-daro, Sindh 2010-05-26

Qatar

 50.4 °C (122.7 °F) Doha 2010-07-14

Saudi Arabia

 52.0 °C (125.6 °F) Jeddah 2010-06-22

Thailand

 44.5 °C (112.1 °F) Uttaradit 1960-04-27

Turkey

 48.8 °C (119.8 °F) Mardin 1993-08-14

Oceania

 50.7 °C (123.3 °F) Oodnadatta, South Australia, Australia 1960-01-02

South America

 49.1 °C (120.4 °F) Villa de María, Argentina 1920-01-02

Paraguay

 45 °C (113 °F) Pratts Gill, Boquerón Department 2009-11-14

Uruguay

 44 °C (111.2 °F) Paysandú, Paysandú Department 1943-01-20

Central America and Caribbean Islands

 45 °C (113 °F) Estanzuela, Zacapa Guatemala  ?

Europe

 48.0 °C or 48.5 °C (118.4 °F or 119.3 °F) Athens, Greece or Catenuova, Italy (Catenanuova’s record is disputed) 1977-07-10 or 1999-08-10;

Bosnia and Herzegovina

 46.2 °C (115.16 °F) Mosta (Herzegovina, Federation of Bosnia and Herzegovina) 1900-07-31

Cyprus

 46.6 °C (115.9 °F) Letkoniko, Cyprus 2010-08-01

Italy

 47 °C or 48.5 °C (116.6 or 119.3 °F) Foggia, Apulia or Catenuuova, Sicily (Catenanuova’s record is disputed) 2007-06-25 and 1999-08-10

Macedonia

 45.7 °C(114.26 °F) Demir Kapija, Demir Kapija Municipality 2007-07-24

Portugal

 47.4 °C (117.3 °F) Amarelja, Beja 2003-08-01

Serbia

 44.9 °C (112.8 °F) Smederevska Palanka, Podunavlie Distrrict, 2007-07-24

Spain

 47.2 °C (116.9 °F) Murcia 1994-07-04

Antarctica

 14.6 °C (59 °F) Vanda Station, Scott Coast 1974-01-05

It seems a disproportionate number of these hot temperatures have been recorded since 2000, eh?

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Researchers find ‘dark state’ transforms light and could lead to better solar energy harvesting

Friday, April 5th, 2013

Researchers at the University of Toronto (Canada) and the University of Glasgow (Scotland) have observed a dark state in caretinoids that is helps plants harvest solar energy (photosynthesis) more efficiently. From the April 4, 2013 news release on EurekAlert,

Pigments found in plants and purple bacteria employed to provide protection from sun damage do more than just that. Researchers from the University of Toronto and University of Glasgow have found that they also help to harvest light energy during photosynthesis.

Carotenoids, the same pigments which give orange color to carrots and red to tomatoes, are often found together in plants with chlorophyll pigments that harvest solar energy. Their main function is photoprotection when rays of light from the sun are the most intense. However, a new study published in Science this week shows how they capture blue/green light and pass the energy on to chlorophylls, which absorb red light.

“This is an example of how nature exploits subtleties that we would likely overlook if we were designing a solar energy harvester,” says Greg Scholes, the D.J. LeRoy Distinguished Professor in the Department of Chemistry at the University of Toronto and lead author of the study.

Advanced optical probes using femtosecond lasers enable light harvesting processes to be examined in exquisite detail. Anticlockwise from top right: Purple bacteria and the structure of the light harvesting complex that gives these cells their distinctive purple colour. This special protein incorporates molecules of bacteriochlorophyll and carotenoid to capture the energy from sunlight. The lower part of the figure shows the protein data recorded from two-dimensional laser spectroscopy. (Illustration: Credit: Evgeny Ostroumov Courtesy: University of Toronto

Advanced optical probes using femtosecond lasers enable light harvesting processes to be examined in exquisite detail. Anticlockwise from top right: Purple bacteria and the structure of the light harvesting complex that gives these cells their distinctive purple colour. This special protein incorporates molecules of bacteriochlorophyll and carotenoid to capture the energy from sunlight. The lower part of the figure shows the protein data recorded from two-dimensional laser spectroscopy. (Illustration:
Credit: Evgeny Ostroumov Courtesy: University of Toronto

The April 4, 2013 University of Toronto news release, which originated the EurekAlert news release, provides some details about the research,

A series of experiments showed that a special “dark state” of the carotenoid – a hidden level not used for light absorption at all – acts as a mediator to help pass the energy it absorbs very efficiently to a chlorophyll pigment.

The researchers performed broadband two-dimensional electronic spectroscopy – a technique used to measure the electronic structure and its dynamics in atoms and molecules – on light-harvesting proteins from purple bacteria. The aim was to characterize in more detail the whole sequence of quantum mechanical states of carotenoids that capture light and channel energy to bacteriochlorophyll molecules. The data revealed a signature of a special state in this sequence that was predicted decades earlier, and sought ever since. The results point to this state’s role in mediating energy flow from carotenoid to bacteriochlorophyll.

“It is utterly counter-intuitive that a state not participating in light absorption is used in this manner,” says Scholes. “It is amazing that nature uses so many aspects of a whole range of quantum mechanical states in carotenoid molecules, moreover, and puts those states to use in such diverse ways.”

The other significant aspect of the work is that the existence of these dark states has been speculated for decades and that the report by Scholes and his colleagues is the clearest evidence to date of their existence.

The implications of this observation (from the University of Toronto news release),

“The energy transfer processes in natural light-harvesting systems have been intensively studied for the last 60 years, yet certain details of the underlying mechanisms remain controversial. Our work really clears up this particular mystery,” says Richard Cogdell, the Hooker Professor of Botany at the University of Glasgow, co-author of the report.

“It makes us look differently at the potential of molecules as building blocks,” Scholes says. “Just imagine one molecule, a carotenoid, that can be used to harvest light, photoprotect, convert to a ‘safety valve’ in bright light to dissipate excitations, or even be employed as a heat transducer by purple bacteria such as are found in the black hole on the island of San Andros in the Bahamas.”

The University of Glasgow also issued a news release about this work on April 5, 2013.

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Bacteria on a battery can be a good thing

Tuesday, March 26th, 2013

In a joint project between the UK’s University of East Anglia (UEA) and the Pacific Northwest National Laboratory (PNNL) in Washington State (US) researchers have published a paper about their work utilizing bacteria to produce electric currents in batteries. From the Mar. 25, 2013 news item on ScienceDaily,

Scientists at the University of East Anglia have made an important breakthrough in the quest to generate clean electricity from bacteria.

Findings published today in the journal Proceedings of the National Academy of Sciences (PNAS) show that proteins on the surface of bacteria can produce an electric current by simply touching a mineral surface.

The research shows that it is possible for bacteria to lie directly on the surface of a metal or mineral and transfer electrical charge through their cell membranes. This means that it is possible to ‘tether’ bacteria directly to electrodes — bringing scientists a step closer to creating efficient microbial fuel cells or ‘bio-batteries’.

The team collaborated with researchers at Pacific Northwest National Laboratory in Washington State in the US.

Shewanella oneidensis (pictured) is part of a family of marine bacteria. The research team created a synthetic version of this bacteria using just the proteins thought to shuttle the electrons from the inside of the microbe to the rock.

Image: Shewanella oneidensis bacteria, Alice Dohnalkova. (downloaded from http://www.uea.ac.uk/mac/comm/media/press/2013/March/bio-batteries)

Image: Shewanella oneidensis bacteria, Alice Dohnalkova. (downloaded from http://www.uea.ac.uk/mac/comm/media/press/2013/March/bio-batteries)

The Mar. 25, 2013 UEA news release,which originated the news item,  describes the work n some detail (Note: A link has been removed),

They inserted these proteins into the lipid layers of vesicles, which are small capsules of lipid membranes such as the ones that make up a bacterial membrane. Then they tested how well electrons travelled between an electron donor on the inside and an iron-bearing mineral on the outside.

Lead researcher Dr Tom Clarke from UEA’s school of Biological Sciences said: “We knew that bacteria can transfer electricity into metals and minerals, and that the interaction depends on special proteins on the surface of the bacteria. But it was not been clear whether these proteins do this directly or indirectly though an unknown mediator in the environment.

“Our research shows that these proteins can directly ‘touch’ the mineral surface and produce an electric current, meaning that is possible for the bacteria to lie on the surface of a metal or mineral and conduct electricity through their cell membranes.

“This is the first time that we have been able to actually look at how the components of a bacterial cell membrane are able to interact with different substances, and understand how differences in metal and mineral interactions can occur on the surface of a cell.

“These bacteria show great potential as microbial fuel cells, where electricity can be generated from the breakdown of domestic or agricultural waste products.

“Another possibility is to use these bacteria as miniature factories on the surface of an electrode, where chemicals reactions take place inside the cell using electrical power supplied by the electrode through these proteins.”

Biochemist Liang Shi of Pacific Northwest National Laboratory said: “We developed a unique system so we could mimic electron transfer like it happens in cells. The electron transfer rate we measured was unbelievably fast – it was fast enough to support bacterial respiration.”

This work reminds me of the biobattery created at Concordia University (my April 20, 2012 posting) and the work on breathable batteries at the Polish Academy of Sciences (my Mar. 8, 2013 posting).

Interested parties can find a full citation for the UEA/PNNL research paper at the bottom of the ScienceDaily news item here.

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Solar cells made even more leaflike with inclusion of nanocellulose fibers

Tuesday, March 26th, 2013

Researchers at the US Georgia  Institute of Technology (Georgia Tech)  and Purdue University (Indiana) have used cellulose nanocrystals (CNC), which is also known as nanocrystalline cellulose (NCC), to create solar cells that have greater efficiency and can be recycled. From the Mar. 26, 2013 news item on Nanowerk,

Georgia Institute of Technology and Purdue University researchers have developed efficient solar cells using natural substrates derived from plants such as trees. Just as importantly, by fabricating them on cellulose nanocrystal (CNC) substrates, the solar cells can be quickly recycled in water at the end of their lifecycle.

The Georgia Tech Mar. 25, 2013 news release, which originated the news item,

The researchers report that the organic solar cells reach a power conversion efficiency of 2.7 percent, an unprecedented figure for cells on substrates derived from renewable raw materials. The CNC substrates on which the solar cells are fabricated are optically transparent, enabling light to pass through them before being absorbed by a very thin layer of an organic semiconductor. During the recycling process, the solar cells are simply immersed in water at room temperature. Within only minutes, the CNC substrate dissolves and the solar cell can be separated easily into its major components.

Georgia Tech College of Engineering Professor Bernard Kippelen led the study and says his team’s project opens the door for a truly recyclable, sustainable and renewable solar cell technology.

“The development and performance of organic substrates in solar technology continues to improve, providing engineers with a good indication of future applications,” said Kippelen, who is also the director of Georgia Tech’s Center for Organic Photonics and Electronics (COPE). “But organic solar cells must be recyclable. Otherwise we are simply solving one problem, less dependence on fossil fuels, while creating another, a technology that produces energy from renewable sources but is not disposable at the end of its lifecycle.”

To date, organic solar cells have been typically fabricated on glass or plastic. Neither is easily recyclable, and petroleum-based substrates are not very eco-friendly. For instance, if cells fabricated on glass were to break during manufacturing or installation, the useless materials would be difficult to dispose of. Paper substrates are better for the environment, but have shown limited performance because of high surface roughness or porosity. However, cellulose nanomaterials made from wood are green, renewable and sustainable. The substrates have a low surface roughness of only about two nanometers.

“Our next steps will be to work toward improving the power conversion efficiency over 10 percent, levels similar to solar cells fabricated on glass or petroleum-based substrates,” said Kippelen. The group plans to achieve this by optimizing the optical properties of the solar cell’s electrode.

The news release also notes the impact that using cellulose nanomaterials could have economically,

There’s also another positive impact of using natural products to create cellulose nanomaterials. The nation’s forest product industry projects that tens of millions of tons of them could be produced once large-scale production begins, potentially in the next five years.

One might almost  suspect that the forest products industry is experiencing financial difficulty.

The researchers’ paper was published by Scientific Reports, an open access journal from the Nature Publishing Group,

Recyclable organic solar cells on cellulose nanocrystal substrates by Yinhua Zhou, Canek Fuentes-Hernandez, Talha M. Khan, Jen-Chieh Liu, James Hsu, Jae Won Shim, Amir Dindar, Jeffrey P. Youngblood, Robert J. Moon, & Bernard Kippelen. Scientific Reports  3, Article number: 1536  doi:10.1038/srep01536 Published 25 March 2013

In closing, the news release notes that a provisional patent has been filed at the US Patent Office.And one final note, I have previously commented on how confusing the reported power conversion rates are. You’ll find a recent comment in my Mar. 8, 2013 posting about Ted Sargent’s work with colloidal quantum dots and solar cells.

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Astonishing material, multi-use titanium dioxide nanofibres

Wednesday, March 20th, 2013

The enthusiasm in the Mar. 20, 2013 news release on EurekAlert about Darren Sun’s work with titanium dioxide nanofibres seems boundless,

A new wonder material that can generate hydrogen, produce clean water and even create energy.

Science fiction? Hardly, and there’s more – It can also desalinate water, be used as flexible water filtration membranes, help recover energy from desalination waste brine, be made into flexible solar cells and can also double the lifespan of lithium ion batteries. With its superior bacteria-killing capabilities, it can also be used to develop a new type of antibacterial bandage.

Scientists at Nanyang Technological University (NTU) in Singapore, led by Associate Professor Darren Sun have succeeded in developing a single, revolutionary nanomaterial that can do all the above and at very low cost compared to existing technology.

The Nanyang Technological University Mar. 20, 2013 news release (also posted to EurekAlert) gives details about how Sun created his ‘wonder’ material,

This breakthrough which has taken Prof Sun five years to develop is dubbed the Multi-use Titanium Dioxide (TiO2). It is formed by turning titanium dioxide crystals into patented nanofibres, which can then be easily fabricated into patented flexible filter membranes which include a combination of carbon, copper, zinc or tin, depending on the specific end product needed.

Titanium dioxide is a cheap and abundant material, which has been scientifically proven to have the ability to accelerate a chemical reaction (photocatalytic) and is also able to bond easily with water (hydrophilic).

Prof Sun, 52, from NTU’s School of Civil and Environmental Engineering, said such a low-cost and easily produced nanomaterial is expected to have immense potential to help tackle ongoing global challenges in energy and environmental issues.

With the world’s population expected to hit 8.3 billion by 2030, there will be a massive increase in the global demand for energy and food by 50 per cent and 30 per cent for drinking water (Population Institute report, titled 2030: The “Perfect Storm” Scenario).

“While there is no single silver bullet to solving two of the world’s biggest challenges: cheap renewable energy and an abundant supply of clean water; our single multi-use membrane comes close, with its titanium dioxide nanoparticles being a key catalyst in discovering such solutions,” Prof Sun said. “With our unique nanomaterial, we hope to be able to help convert today’s waste into tomorrow’s resources, such as clean water and energy.”

Prof Sun had initially used titanium dioxide with iron oxide to make anti-bacterial water filtration membranes to solve biofouling – bacterial growth which clogs up the pores of membranes, obstructing water flow.

While developing the membrane, Prof Sun’s team also discovered that it could act as a photocatalyst, turning wastewater into hydrogen and oxygen under sunlight while still producing clean water. Such a water-splitting effect is usually caused by Platinum, a precious metal that is both expensive and rare.

Here’s a list of what the researchers are claiming multi-use titanium dioxide materials can accomplish, from the news release,

Producing hydrogen and clean water

This discovery, which was published recently in the academic journal, Water Research, showed that a small amount of nanomaterial (0.5 grams of titanium dioxide nanofibres treated with copper oxide), can generate 1.53 millilitre of hydrogen in an hour when immersed in one litre of wastewater. This amount of hydrogen produced is three times more than when Platinum is used in the same situation.

Depending on the type of wastewater, the amount of hydrogen generated can be as much as 200 millilitres in an hour. Also to increase hydrogen production, more nanomaterial can be used in larger amounts of wastewater.

Producing low-cost flexible forward osmosis membranes

Not only can titanium dioxide particles help split water, it can also make water filter membranes hydrophilic – allowing water to flow through it easily, while rejecting foreign contaminants, including those of salt, making it perfect for desalinating water using forward osmosis. Thus a new super high flux (flow rate) forward osmosis membrane is developed.

This discovery was published recently in last month’s journal of Energy and Environmental Science. This is the first such report of TiO2 nanofibres and particles used in forward osmosis membrane system for clean water production and energy generation.

Producing new antibacterial bandages

With its anti-microbial properties and low cost, the membrane can also be used to make breathable anti-bacterial bandages, which would not only prevent infections and tackle infection at open wounds, but also promote healing by allowing oxygen to permeate through the plaster.

The membrane’s material properties are also similar to polymers used to make plastic bandages currently sold on the market.

Producing low-cost flexible solar cells

Prof Sun’s research projects have shown out that when treated with other materials or made into another form such as crystals, titanium dioxide can have other uses, such as in solar cells.

By making a black titanium dioxide polycrystalline sheet, Prof Sun’s team was able to make a flexible solar-cell which can generate electricity from the sun’s rays.

Producing longer lasting lithium ion batteries

Concurrently, Prof Sun has another team working on developing the black titanium dioxide nanomaterial to be used in Lithium ion batteries commonly used in electronic devices.

Preliminary results from thin coin-like lithium ion batteries, have shown that when titanium dioxide sphere-like nanoparticles modified with carbon are used as the anode (negative pole), it can double the capacity of the battery. This gives such batteries a much longer lifespan before it is fully drained. The results were featured prominently in a highly respected Journal of Materials Chemistry on its cover page last year.

As is expected these days, from the news release,

Next step – commercialisation

Prof Sun and his team of 20, which includes 6 undergraduates, 10 PhD students and 4 researchers, are now working to further develop the material while concurrently spinning off a start-up company to commercialise the product.

They are also looking to collaborate with commercial partners to speed up the commercialisation process.

Here’s a citation and a link for the paper,

Novel-Structured Electrospun TiO2/CuO Composite Nanofibers for High Efficient Photocatalytic Cogeneration of Clean Water and Energy from Dye Wastewater by Siew Siang Lee, Hongwei Bai Zhaoyang Liu, & Darren Delai Sun. Water Research Available online 19 March 2013 In Press, Accepted Manuscript http://dx.doi.org/10.1016/j.watres.2012.12.044

This paper is behind a paywall. Good luck to Professor Sun and his colleagues.

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Dublin (Ireland) hosts Europe’s largest nanotechnology conference

Thursday, March 14th, 2013

The announcement of Dublin’s nano hosting duties is in a Mar. 14, 2013 news item on Nanowerk  (Note: A link has been removed),

The 6th biannual conference, EuroNanoForum 2013, will gather experts and decision-makers of the nanotechnology community to Dublin this June. EuroNanoForum 2013 is the largest nanotechnology conference in Europe and will focus on the impact of nanotechnology in improving people’s lives, especially in the key societal sectors such as health, energy and environment. The event coincides with Nanotech Europe exhibition and the Nanoweek Ireland.

“The conference showcases innovation as a driver of economic growth. New technologies arising from nano-science and their applications are presented and potential new end products are discussed”, describes Herbert von Bose, Director, European Commission, DG Research & Innovation, Industrial Technologies.

The EuroNanoForum March 14, 2013 news release, which originated the news item, can be found here.

The forum organizers have created a Hot Topics page on the conference website (you can register for EuroNanoForum 2013 here) which provides some compelling reasons for attending,

Self-cleaning walls, lightweight airplanes and hydrogen fueled scooters drive the nano-future at EuroNanoForum 2013

We claim that by 2030, Europe will be a frontrunner in sustainable economy. The European Cleantech sector is steadily growing and it is taking a leading position in the global markets.  Companies, nations, and international consortia will capitalise on the business opportunity and what we have so far seen is just the tip of a vastly growing iceberg.

In EuroNanoForum 2013 Henning Zoz, the President of the Zoz Group, will present a concept which will revolutionize the refueling infrastructure. In the plenary, Nano in everyday life, he will elaborate on his company’s innovation – small tank cartridges containing nanostructured powder that can store an enormous amount of hydrogen virtually without pressure. With such changeable tanks it is already possible to drive a scooter, at Zoz GmbH in Wenden. The innovation ensures that surplus electricity output from renewable energy sources economically converted into hydrogen can be consumed as transportation-fuel.

Cure for cancer and improving hearing implants

Hans Hofstraat, VP of Philips Healthcare, and Patrick Boisseau, the Chairman of the ETP Nanomedicine, will lead the cadre of healthcare specialists in EuroNanoForum 2013. In Dublin we will hear what is the role of nanotechnology in answering the societal challenge of ageing populations. Moreover, will nano make vital medicine available to all people – not only in Europe but worldwide?

Over 60 million citizens in the EU suffer from hearing loss with its associated restrictions. Pascal Senn, Project Coordinator of NanoCi project from University of Bern, will present on the first conference day at the Healthcare session, how their project is developing implants to improve hearing. Using functional nano-materials, including carbon nanotubes, NanoCi aims at developing a cost-efficient and fully implantable neuro-prosthesis with substantially increased sound quality.

The Graphene Flagship will sail to EuroNanoForum 2013

The European Commission has chosen Graphene as one of Europe’s first 10-year, 1,000 million euro FET flagships. The mission of the flagship is to take graphene and related layered materials from academic laboratories to society, revolutionize multiple industries and create economic growth and new jobs in Europe. The Graphene flagship is a new form of joint, coordinated research initiative of unprecedented scale. It brings together an academic-industrial consortium aiming at a breakthrough for technological innovation. Involved are Nobel Laureates, top-notch research groups and the next generation industrial leaders.

From the start in 2013 the Graphene Flagship will coordinate 126 academic and industrial research groups in 17 European countries with an initial 30-month-budget of 54 million euro. The consortium will be extended with another 20-30 groups through an open call, issued soon after the start of the initiative, just after EuroNanoForum 2013. Will you sail with the ship or be left behind on the shore?

Wish I could be there.

ETA Apr. 22, 2013: Drat! I don’t like it when someone else does it. Well, I like it even less when I do it! I see the dates EuroNanoforum dates are not mentioned, they are June 18 – 20, 2013.

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University of Toronto’s Ted Sargent and his colloidal quantum dots make news again

Friday, March 8th, 2013

Ted Sargent at the University of Toronto is one of the most consistent communicators, in Canada, about nanoscale research. His work is focused on solar panels/cells and colloidal quantum dots and according to a Mar. 7, 2013 news release on EurekAlert, there have been some new developments,

A new technique developed by U of T Engineering Professor Ted Sargent and his research group could lead to significantly more efficient solar cells, according to a recent paper published in the journal Nano Letters.

The paper, “Jointly-tuned plasmonic-excitonic photovoltaics using nanoshells,” describes a new technique to improve efficiency in colloidal quantum dot photovoltaics, a technology which already promises inexpensive, more efficient solar cell technology. Quantum dot photovoltaics offers the potential for low-cost, large-area solar power – however these devices are not yet highly efficient in the infrared portion of the sun’s spectrum, which is responsible for half of the sun’s power that reaches the Earth.

The solution? Spectrally tuned, solution-processed plasmonic nanoparticles. These particles, the researchers say, provide unprecedented control over light’s propagation and absorption.

The new technique developed by Sargent’s group shows a possible 35 per cent increase in the technology’s efficiency in the near-infrared spectral region, says co-author Dr. Susanna Thon. Overall, this could translate to an 11 per cent solar power conversion efficiency increase, she says, making quantum dot photovoltaics even more attractive as an alternative to current solar cell technologies.

The University of Toronto Mar. 7, 2013 news release written by Terry Lavender, which is the original of the one on EurekAlert, goes on to explain the interest in colloidal quantum dots and to describe the new technique,

“There are two advantages to colloidal quantum dots,” Thon says. “First, they’re much cheaper, so they reduce the cost of electricity generation measured in cost per watt of power. But the main advantage is that by simply changing the size of the quantum dot, you can change its light-absorption spectrum.

“Changing the size is very easy, and this size-tunability is a property shared by plasmonic materials: by changing the size of the plasmonic particles, we were able to overlap the absorption and scattering spectra of these two key classes of nanomaterials.”

Sargent’s group achieved the increased efficiency by embedding gold nanoshells directly into the quantum dot absorber film. Gold is not usually thought of as an economical material but researchers say lower-cost metals can be used to implement the same concept proved by Thon and her co-workers.

It’s exciting work and a 35% increase in efficiency sounds great, although the base efficiency isn’t mentioned. If your base is one and you increase it to two, you have a 100% increase. As I noted in my July 30, 2012 posting about the team’s last breakthrough which showed a 37% increase in efficiency for their technique but actually worked out to a 7% increase for solar cell efficiency,

I think the excitement over 7% indicates just how much hard work the researchers have accomplished to achieve this efficiency. It reminds me of reading about the early development of electricity (Power struggles; Scientific authority and the creation of practical electricity before Edison by Michael Brian Schiffer)  where accomplishments we would now consider minuscule built careers.

These increases  may be small but they are important not only for the development of solar cells but also as an illustration of how scientific breakthroughs are often a series of small steps and of the infinite patience exercised by researchers.

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It takes more than research to change energy sources and use

Thursday, February 14th, 2013

Much of the talk about reducing or eliminating dependency on fossil fuels is focused on research to accomplish these goals or policies to support and promote new patterns of energy use as opposed to the details needed to implement a change in the infrastructures. For example, one frequently sees news about various energy research efforts such as this one at the University of Texas at Dallas featured in a Feb. 14, 2013 news item on Azonano,

University of Texas at Dallas researchers and their colleagues at other institutions are investigating ways to harvest energy from such diverse sources as mechanical vibrations, wasted heat, radio waves, light and even movements of the human body.

The goal is to develop ways to convert this unused energy into a form that can self-power the next generation of electronics, eliminating or reducing the need for bulky, limited-life batteries.

Beyond the more familiar wind and solar power, energy harvesting has a wide range of potential applications. These include: powering wireless sensor networks placed in “intelligent” buildings, or in hard-to-reach or dangerous areas; monitoring the structural health of aircraft; and biomedical implants that might transmit health data to your doctor or treat a chronic condition.

The Feb. 14, 2013 University of Texas at Dallas news release, which originated the news item, describes a recent energy research event and highlights some of the work being performed by the Center for Energy Harvesting Materials and Systems (CEHMS) consortium (Note: A link has been removed),

At a recent scientific conference held at UT Dallas, experts from academia, industry and government labs gathered to share their latest research on energy harvesting. Energy Summit 2013 focused on research initiatives at UT Dallas, Virginia Tech and Leibniz University in Germany, which form a consortium called the Center for Energy Harvesting Materials and Systems (CEHMS).

Founded in 2010, CEHMS is an Industry/University Cooperative Research Center funded in part by the National Science Foundation. It includes not only academic institutions, but also corporate members who collaborate on research projects and also provide funding for the center.  Roger Nessen, manager of sales and marketing at Exelis Inc. is chairman of the CEHMS advisory board.

Here are some examples of the research,

For example, Dr. Mario Rotea, the Erik Jonsson Chair and head of the Department of Mechanical Engineering at UT Dallas, discussed some of his work aimed at advancing the development of wind energy systems. He represents UT Dallas in a proposed new consortium of universities and companies called WindSTAR that would collaborate with CEHMS on wind energy science and technology issues.

On the chemistry front, Smith’s [Dennis Smith, co-director of CEHMS and the Robert A. Welch Distinguished Chair in Chemistry at UT Dallas] synthetic chemistry lab is working with advanced materials that use piezoelectrics. If a piezoelectric material is deformed by a mechanical stress – such as stepping on it or subjecting it to vibrations – it produces an electric current. Smith’s lab is investigating whether the addition of nanoparticles to certain piezoelectric materials can boost this so-called piezoelectric effect.

CEHMS co-director Dr. Shashank Priya, professor of mechanical engineering and the James and Elizabeth Turner Fellow of Engineering at Virginia Tech, collaborates with Smith on piezoelectric research. Among many projects, researchers at Virginia Tech are incorporating piezoelectrics into “smart” tiles that produce electricity when stepped upon, as well as into materials that might be applied like wallpaper to gather light and vibrational energy from walls.

Other university and industry projects include:

  • Investigating how to redesign systems to require less power.
  • An intelligent tire system that harvests energy from the vibrations in a rotating tire, powering embedded sensors that gather and report data on tire pressure, tire conditions and road conditions.
  • A new class of magnetoelectric materials that can simultaneously convert magnetic fields and vibrations into energy.
  • A textile-type material that converts wasted thermal energy into electricity, which could be wrapped around hot pipes or auto exhaust pipes to generate power.
  • Flexible solar cells that could be integrated into textiles, and worn by hikers or soldiers to power portable electronic devices far away from an electric socket.

It’s exciting to talk about research, startups, and policies but at some point one needs to develop an infrastructure to support these efforts as Kyle Vanhemert points out (in an elliptical fashion) in his Feb.14, 2013 article, A Deeply Thought-Out Plan for EV [electric vehicle] Charging Stations, on the Fast Company website,

Currently, the best estimates suggest that upwards of 80% of electric vehicle charging happens at home. … If we want to see wider adoption of EVs, however, one thing is obvious: We need to make it possible for drivers to charge in places other than their garage. It’s a more complex problem than it might seem, but a series of reports by the New York-based architecture and design studio WXY will at least give urban planners and prospective charging station entrepreneurs a place to start.

The studies, sponsored by the U.S. Department of Energy and the New York State Energy Research and Development Authority, address a major obstacle standing in the way of more ubiquitous charging–namely, that no one knows exactly what ubiquitous charging looks like. And in fairness, that’s because it doesn’t look like any one thing.  …

The WXY design studio has developed guidelines for these hypothetical EV charging stations,

The study identifies 22 design elements in all, divided into three categories: installation, access, and operation. The first looks at the infrastructural nuts and bolts of the site, including factors like physical dimensions of the station and its proximity to the power grid. Access deals with the factors that shape the basic user experience, things like proximity to traffic and building entrances, lighting, and signage. …

Vanhemert’s article includes some design diagrams, more details about these charging stations, and links to the design studio’s report and other reports that have been commissioned for the US Northeast Electric Vehicle Network.

Thank you to Kyle Vanhemert for a thought-provoking article, which raises questions about what kinds of changes will need to be made to infrastructure and everyday gadgets as we transition to new energy sources.

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