1)      Patently Curious - MAKE magazine #09 features Valone

2)      Superconductivity and Magnetism in Harmony – First time ever

3)      Cheap Nano Solar Cells – Nanotubes use indoor light for electricity

4)      New Look for Solar Cells – Nanotechweb’s view of #3 story

5)      Flexible Solar Panels – Gets the USDOE Secretary’s attention

6)   Expanding Nuclear Recycling - Public critical of more nukes

7)   Hot Advances in Thermoelectrics - Organics can generate electricity

Magnetism and superconductivity are often thought to be incompatible. However, physicists in the US and France have created a nanoscale structure that contains both magnetic and superconducting properties at the same time. The results show a hitherto undocumented interplay between ferromagnetism and superconductivity and the researchers will be studying the phenomenon at the Swiss Light Source, at the Paul Scherrer Institute, over the next two years.

According to the Bardeen-Cooper-Schrieffer theory of superconductivity, electrons with opposite spins form pairs that can move through a material without resistance. A magnetic field can destroy superconductivity in two ways: by breaking up the electron pair, or by trying to make both of the electron spins point in the same direction. These effects also limit how much current can flow through the superconductor because of the disruptive effect of the magnetic field produced by the current itself.

Last year, Jacques Chakhalian and colleagues at the Max Planck Institute, Germany, and the University of Grenoble, France, published a paper in Nature Physics, documenting novel properties at the interface between a superconductor made from yttrium, barium copper and oxygen and a ferromagnet made from lanthanum calcium manganese oxide (LCMO). The researchers developed a technique that allowed them to combine the two materials in one thin-film superlattice, which showed both superconducting and magnetic properties.

Chakhalian and colleagues now plan to look more closely at the interface between the two materials using synchrotron light (electromagnetic radiation of varying wavelengths that can be tuned to a specific wavelength for a particular experiment). To help them do this, the researchers have been awarded research time and financial support over the next two years, at the Swiss Light Source – the most advanced synchrotron light source in the world.

The spectrum at the Swiss Light Source varies from infrared light to soft and hard X-rays. However, unlike conventional X-rays, which diffuse through space, the light beams from the synchrotron are sharply focused. The main technical challenge for Chakhalian and his team will now be to focus the beam of low-energy photons into a spot the size of a few hundred microns.

 3) Cheap Nano Solar Cells

Kevin Bullis,  March 5, 2007, http://www.technologyreview.com/Nanotech/18259/

Carbon nanotubes could help make nanoparticle-based solar cells more efficient and practical.

Researchers at University of Notre Dame, in Indiana, have demonstrated a way to significantly improve the efficiency of solar cells made using low-cost, readily available materials, including a chemical commonly used in paints. The researchers added single-walled carbon nanotubes to a film made of titanium-dioxide nanoparticles, doubling the efficiency of converting ultraviolet light into electrons when compared with the performance of the nanoparticles alone. The solar cells could be used to make hydrogen for fuel cells directly from water or for producing electricity. Titanium oxide is a main ingredient in white paint.

The approach, developed by Notre Dame professor of chemistry and biochemistry Prashant Kamat http://www.nd.edu/~pkamat/ and his colleagues, addresses one of the most significant limitations of solar cells based on nanoparticles. (See "Silicon and Sun http://www.technologyreview.com/Nanotech/17726/") Such cells are appealing because nanoparticles have a great potential for absorbing light and generating electrons. But so far, the efficiency of actual devices made of such nanoparticles has been considerably lower than that of conventional silicon solar cells. That's largely because it has proved difficult to harness the electrons that are generated to create a current.

Indeed, without the carbon nanotubes, electrons generated when light is absorbed by titanium-oxide particles have to jump from particle to particle to reach an electrode. Many never make it out to generate an electrical current. The carbon nanotubes "collect" the electrons and provide a more direct route to the electrode, improving the efficiency of the solar cells. As they wrote online in the journal Nano Letters, the Notre Dame researchers form a mat of carbon nanotubes on an electrode. The nanotubes serve as a scaffold on which the titanium-oxide particles are deposited. "This is a very simple approach for bringing order into a disordered structure," Kamat says.

The new carbon-nanotube and nanoparticle system is not yet a practical solar cell. That's because titanium oxide only absorbs ultraviolet light; most of the visible spectrum of light is reflected rather than absorbed. But researchers have already demonstrated ways to modify the nanoparticles to absorb the visible spectrum. In one strategy, a one-molecule-thick layer of light-absorbing dye is applied to the titanium-dioxide nanoparticles. Another approach, which has been demonstrated experimentally by Kamat, is to coat the nanoparticles with quantum dots--tiny semiconductor crystals. Unlike conventional materials in which one photon generates just one electron, quantum dots have the potential to convert high-energy photons into multiple electrons.

4) New Look for Solar Cells

March 7, 2007, Nanotechweb News,  http://nanotechweb.org/articles/news/6/3/7/1#070307

Researchers in the US have shown that carbon nanotubes can significantly improve the efficiency of solar cells made of titanium dioxide, a readily available and cheap chemical routinely used in paint and sunscreen. Prashant Kamat and colleagues at the University of Notre Dame, Indiana, anchored titanium dioxide nanoparticles on single-walled carbon nanotubes and found that the efficiency of converting ultraviolet light into current was doubled compared to that using the nanoparticles alone.

Researchers are interested in using the photocatalytic activity of nanostructured semiconductor films to design solar cells. Of particular importance is the dye-sensitized solar cell, which uses nanostructured titanium dioxide (TiO2) films modified with sensitizing dyes. Such cells are appealing because nanoparticles have a great potential for absorbing light and generating electrons. However, despite the initial success of achieving 10% solar conversion efficiency, efforts to further improve their performance have been difficult and the performance of devices made of such cells lies well below that of conventional silicon solar cells. This is because it is difficult to harness all the electrons generated in the nanostructured TiO2 cells to create a current.

Now, Kamat and colleagues have used carbon nanotubes to direct the flow of photogenerated charge carriers so that they can reach an electrode more easily, where they can then generate an electrical current. The nanotubes effectively "collect" the electrons and provide a more direct route to the electrode, therefore improving the efficiency of the solar cells.

The Notre Dame researchers achieved their result by forming a mat of carbon nanotubes on carbon fibre and glass electrodes. The nanotubes serve as a scaffold on which TiO2 particles are then deposited. Kamat says that this is a very simple solution for bringing order into a disordered structure.

The new carbon nanotube-nanoparticle system has not yet been made into a practical solar cell because the TiO2 only absorbs ultraviolet light – most of the visible spectrum of light is reflected. However, the researchers say they have already shown ways to absorb light in the visible region too, by coating the nanoparticles with quantum dots (tiny semiconductor crystals). Here, the dots can convert high-energy photons into multiple electrons, unlike in conventional materials in which one photon generates just one electron.

The researchers reported their work in Nano Lett..

5) Wireless, Flexible Solar Technology Gets White House Backing

Associated Press, March 08, 2007, http://www.technologyreview.com/Wire/18298/

A company trying to harness energy from sunlight and interior light to wirelessly power everything from cell phones to signboards now has financial backing from the White House. President George W. Bush's program to help solar energy compete with conventional electricity sources will help fund Konarka Technologies' development of flexible plastic solar cell strips -- material that could be embedded into the casings of laptop computers and even woven into power-producing clothing to energize digital media players or other electronics (www.Konarka.com ).

The technology, which received its first Pentagon funding three years ago, offers a lightweight, flexible alternative to conventional rigid photovoltaic cells on glass panels.

Energy Secretary Samuel Bodman is scheduled Thursday afternoon to tour Konarka's headquarters in a former textile mill in Lowell, where he's expected to announce funding from Bush's Solar America Initiative.

The award amount and other details were to be announced in a news conference at Konarka, a six-year-old private company that has attracted nearly $60 million (euro46 million) in venture capital funding. Konarka's nearly $10 million (euro7.6 million) in grant money to date from U.S. and European governments includes funding from the Pentagon to supply lightweight portable battery chargers and material for tents to draw power from sunlight. Chief Executive Howard Berke said the new White House support is a milestone for Konarka.

The first commercial product using Konarka's technology is not expected to hit the market until next year, and the company is not saying what that product might be. Konarka expects to provide prototypes in the second half of this year to commercial partners that would bring the technology to market. Konarka's approach ''is potentially a great breakthrough technology, but like all breakthroughs, they don't happen instantaneously,'' Berke said in a phone interview.

Observers say Konarka has a good chance of becoming a leader in solar power, an industry enjoying a recent surge in initial public stock offerings by startup companies as well as growing investments from traditional energy companies -- for example, one of Konarka's financial backers is Chevron Corp. Konarka's development of plastic solar cell strips that can be manufactured like rolls of photographic film ''has the promise of becoming a low-cost manufacturing technique,'' said Jeffrey Bencik, a Jefferies & Co. analyst who follows the solar industry. ''Some of their laboratory production has worked as advertised. But can they mass-produce it and get the same result? That's the biggest question.''

Among developers of solar technology for small-scale uses, Konarka is ''definitely doing the best job at developing what ultimately will have to be a mass-manufactured material,'' said Dan Nocera, a Massachusetts Institute of Technology chemistry professor.

However, Nocera said it remains to be seen whether Konarka's so-called ''Power Plastic'' is sufficiently chemically stable to convert energy efficiently both when light is dim and when it's bright.

Konarka, which takes its name from an ancient temple in India dedicated to the sun god Surya, was founded by Berke and Alan Heeger, who shared the 2000 Nobel Chemistry prize for showing that certain plastics can be made to conduct electricity. The discovery about polymers -- long considered to be useful only as electrical insulators -- led to the development of new types of plastics to create flexible and lightweight alternatives to traditional solar cells on heavy glass panels.

Konarka developed low-cost plastics that could be used as the top and bottom surfaces of the photovoltaic cell. The 50-employee company says it has more than 280 patents and patent applications for materials, manufacturing and other processes and devices.

The company says its solar cells are efficient across a much broader spectrum of light than traditional cells, allowing them to draw energy from both the sun and indoor lighting. Konarka says its material is lightweight and flexible so that it can be colored, patterned and cut to fit almost any device. The firm envisions embedding its material in cell phones, laptops and toys to provide power on the go. Clothing could be woven with the material to supply power for handheld electronics, and signboards, traffic lights and rooftops could be fitted with solar strips.