The G24i photovoltaic panel will be integrated into a range of bags targeting the consumer market. The panel will harvest energy while used outdoors as well as in low light conditions indoors – [...]]]> G24 Innovations (G24i) and consumer electronics bag manufacturer Mascotte Industrial Associates are announcing the world’s first commercial product using Dye-Sensitized Solar Cells (DSSC):

The G24i photovoltaic panel will be integrated into a range of bags targeting the consumer market. The panel will harvest energy while used outdoors as well as in low light conditions indoors – a unique advantage of the G24i DSSC module – and repower mobile electronic devices such as mobile phones, e-books, cameras, and portable LED lighting systems. The G24i module is based on a technology invented by the internationally acclaimed chemist, Prof. Michael Grätzel, Ph. D, Director, Laboratory of Photonics and Interfaces at the Swiss Federal Institute of Technology (EPFL) in Lausanne.

The University licensed the patent rights to the technology to Solarmer last September. The license covers several polymers under development in Yu’s [...]]]> Solarmer Energy Inc., founded in 2006 to commercialise polymer solar cell technology developed by the Yang Yang group at UCLA, are using a new semiconducting material (”PTB1″) invented by University of Chicago chemists.

The University licensed the patent rights to the technology to Solarmer last September. The license covers several polymers under development in Yu’s laboratory [...].
An advantage of the Chicago technology is its simplicity. Several laboratories around the country have invented other polymers that have achieved efficiencies similar to those of Yu’s polymers, but these require far more extensive engineering work to become a viable commercial product.
“We think that our system has potential,” Yu said. “The best system so far reported is 6.5 percent, but that’s not a single device. That’s two devices.”
By combining Solarmer’s device engineering expertise with Yu and Liang’s semiconducting material, they have been able to push the material’s efficiency even higher.

Via Science Daily

Inspired by the human eye, Ma’s curved photodetector could eliminate that distortion. In the eye, light enters [...]]]> University of Wisconsin-Madison researchers have developed flexible photodetectors consisting of 250 nm thick single-crystal germanium membranes transferred onto 175 µm thick PET substrates using a dry printing technique. This could allow distortion-free photos without the need for fancy lenses.

Inspired by the human eye, Ma’s curved photodetector could eliminate that distortion. In the eye, light enters though a single lens, but at the back of the eye, the image falls upon the curved retina, eliminating distortion. “If you can make a curved imaging plane, you just need one lens,” says Ma. “That’s why this development is extremely important.”

Ma and his group can create curved photodetectors with specially fabricated nanomembranes — extremely thin, flexible sheets of germanium, a very light-sensitive material often used in high-end imaging sensors. Researchers then can apply the nanomembranes to any polymer substrate, such as a thin, flexible piece of plastic. Currently, the group has demonstrated photodetectors curved in one direction, but Ma hopes next to develop hemispherical sensors.

The work has been published in Applied Physics Letters: Flexible photodetectors on plastic substrates by use of printing transferred single-crystal germanium membranes.

[via The Register]

The dye-based organic [...]]]> A team of researchers at MIT, headed by Marc Baldo, have developed solar concentrators based on coatings of organic dyes on glass or plastic substrates. Sunlight absorbed by the dye molecules is re-emitted at different wavelengths and waveguided to the photovoltaic cells at the edge of the glass substrate. From the press release:

The dye-based organic solar concentrator functions without the use of tracking or cooling systems, greatly reducing the overall cost compared to other concentrator technologies. [...] Some light passes through the concentrator and can be absorbed by lower voltage solar cells underneath. Alternatively, the partially transmissive concentrator can function as a window.

In the published work (Science) the dye layers were deposited from the vapor phase, but solution processing is in principle also possible.
Apparently very similar luminescent solar concentrators were first developed in the 1970’s, but suffered from absorption of the light before it reached the edges, as well as poor stability of the dyes.
While the stability of the current devices is also not good enough yet for products, the inventors believe the technology could be commercialized within three years.
Covalent Solar, a company being spun out of MIT by three of its inventors (Michael Currie, Jon Mapel, and Shalom Goffri) is working on achieving this goal.

At ECN, organic photovoltaics are being researched for almost a decade. The knowledge of materials, system designs and production processes has come to a point where transition to large scale [...]]]> The ECN (Energy research Centre of the Netherlands) is teaming up with the Holst Centre to transfer their lab-scale solar cell processing to Roll-to-Roll production:

At ECN, organic photovoltaics are being researched for almost a decade. The knowledge of materials, system designs and production processes has come to a point where transition to large scale manufacturing has to be envisaged.
At Holst Centre, the recently opened Roll-to-Roll research line for printed electronics will be used to complement the knowledge of ECN and support the further research towards low-cost, large-area manufacturing. To guarantee the low-cost potential, the upscaling will initially be done with active materials that are abundantly available, although an eye will be kept on new high-performance materials. In a first phase the investigated processes will be slot-die coating and gravure printing. Within the ECN labs, efficiencies of over 4% have been obtained. Aim is to at least sustain this level of efficiency when going towards roll-to-roll production.
Being research centres, ECN and Holst Centre will not take any of the technology in production themselves. The open-innovation program aims at industrial parties to subscribe and assign resident researchers to join the research teams on site.

today announced it has raised $45 million in private capital financing. The financing was led by Mackenzie Financial Corporation, a leading investment management firm with over $60 billion in assets under management, and was co-led by existing investor, Good Energies, a leading investor in the renewable energy industry. Lead investors from [...]]]> Konarka, developers of organic photovoltaics,

today announced it has raised $45 million in private capital financing. The financing was led by Mackenzie Financial Corporation, a leading investment management firm with over $60 billion in assets under management, and was co-led by existing investor, Good Energies, a leading investor in the renewable energy industry. Lead investors from prior rounds also participated, including Draper Fisher Jurvetson (DFJ), Asenqua Ventures, New Enterprise Associates (NEA) and 3i. Other participating current investors include Vanguard Ventures, Chevron Ventures, Massachusetts Green Energy Fund, NGEN Partners and Angeleno Group. The financing was agented by Lehman Brothers.

have signed a joint agreement to accelerate the development, manufacturing and commercialization of polymer-based organic photovoltaic (OPV) technologies for consumer and electronic applications. Under the agreement, the mutual goal is to bring Konarka’a organic photovoltaic material, Power Plastic®, to market.

“Konarka’s Power Plastic is [...]]]> Konarka (organic photovoltaics) and Toppan Forms (Data Print Services and information management services)

have signed a joint agreement to accelerate the development, manufacturing and commercialization of polymer-based organic photovoltaic (OPV) technologies for consumer and electronic applications. Under the agreement, the mutual goal is to bring Konarka’a organic photovoltaic material, Power Plastic®, to market.

“Konarka’s Power Plastic is flexible, thin, printable and low in cost, providing our organization with promising new business opportunities as we strive to become an integrated information management service company,” commented Masanori Akiyama, president and CEO of Toppan Forms. “With the full-fledged advent of the ubiquitous society under way, we need an ever-present power technology that can be integrated with pervasive networked devices for information collection and distribution. We are delighted to collaborate with Konarka, the world leader in OPV technologies, to accelerate the commercialization of this transformational power technology to the market place.” [...]

“The partnership with Toppan Forms represents a key milestone for the commercialization of Power Plastic,” commented Rick Hess, president and CEO of Konarka. “This relationship enables each company to focus its expertise and resources on key product development processes, continuing our go-to-market strategy of partnering with leading global companies for a variety of applications.”

BASF and Bosch are to cooperate in the innovative field of organic photovoltaics (OPV) and are founding members of the technology initiative of Germany’s Federal Ministry of Education and Research (BMBF). [... ] Last year, photovoltaic modules had a global market volume of €8 billion. The segment is expected to [...]]]> From the Press release: (pdf, html)

BASF and Bosch are to cooperate in the innovative field of organic photovoltaics (OPV) and are founding members of the technology initiative of Germany’s Federal Ministry of Education and Research (BMBF). [... ] Last year, photovoltaic modules had a global market volume of €8 billion. The segment is expected to grow by more than 20 percent annually until 2020. The BMBF will provide €60 million for research to develop this highly attractive market, while the initiative’s current industry partners – which include, alongside BASF and Bosch, Merck (Darmstadt) and Schott (Mainz) – plan to spend up to €300 million. [...]

Stake in Heliatek

To further develop the new technology, BASF and Bosch are also cooperating on special research activities with the Dresden-based company Heliatek GmbH. BASF Venture Capital GmbH and Robert Bosch GmbH are each investing €1.6 million in the start-up company, which was founded in 2006. The other investors are Wellington Partners and the ‘High-Tech Gründerfonds’. Heliatek specializes in the manufacture of new-generation organic solar cells. The company is working on an ultra-efficient technology to build large-scale modules on cheap, flexible substrates using a roll-to-roll production process.

BASF is conducting research into semi-conductive organic materials with high thermal and photo-thermal stability. [...] BASF contributes its broad-based expertise in the field of organic electronics and the design, synthesis and production of complex organic compounds to the project. [...]

The researchers want to develop organic solar cells that convert at least ten percent of the incident light into energy and offer a service life of more than ten years. BASF’s “Joint Innovation Lab – Organic Electronics”, which was opened last year in Ludwigshafen, acts as a cooperation platform for the industry and university partners. Experts from a range of disciplines are also working on organic light emitting diodes (OLEDs) at the JIL, a technology also based, like organic photovoltaics, on organic semi-conductive materials.

an anthracene derivative containing free positive ions and a ruthenium, complex containing negative ions. When the two are joined, ions diffuse across the junction creating a difference in energy levels that facilitates [...]]]> George Malliaras and coworkers at Cornell created a novel type of organic diode with an “ionic junction” by laminating together layers of

an anthracene derivative containing free positive ions and a ruthenium, complex containing negative ions. When the two are joined, ions diffuse across the junction creating a difference in energy levels that facilitates rectification, electroluminiscence and photovoltaic response.

The technique is potentially suitable for low-cost fabrication of flexible photovoltaics and LEDs.

The work is described in the Sept. 7 issue of the journal Science in a paper by Cornell graduate researchers Daniel Bernards and Samuel Flores-Torres, Héctor Abruña, the E. M. Chamot Professor of Chemistry and Chemical Biology at Cornell, and Malliaras.

Markets for OLED and Paper-Like Displays to Total $10.2 Billion by 2011:

Holograms have advantages that make up for their relatively weak concentration power. They can select certain frequencies and focus them on solar cells that work best at [...]]]> Prism Solar Technologies use holograms to concentrate light onto photovoltaic (PV) cells. This allows increased output per cell on partially transparent silicon PV windows. From the MIT Technology Review:

Holograms have advantages that make up for their relatively weak concentration power. They can select certain frequencies and focus them on solar cells that work best at those frequencies, converting the maximum possible light into electricity. They also can be made to direct heat-generating frequencies away from the cells, so the system does not need to be cooled. [...]
Also, different holograms in a concentrator module can be designed to focus light from different angles — so they don’t need moving parts to track the sun.
Cost savings are a major factor for the development of this technology:

The system needs 25 to 85 percent less silicon than a crystalline silicon panel of comparable wattage, Lewandowski says, because the photovoltaic material need not cover the entire surface of a solar panel. [...]
The high demand for solar cells in Germany and other European countries “has now outstripped the supply, which has [led to] a silicon shortage and a shortage of manufacturing in the photovoltaic world,” he says.

Although the idea of holographic solar concentrators has been around since the early 1980s, no one has developed them commercially yet, according to Professor Stojanoff, who has investigated the technique extensively. His company, Holotec GmbH in Aachen, Germany, researches and manufactures holographic materials. Also, Northeast Photosciences, a Hollis, NH-based company, came close to manufacture, before it went defunct for reasons unrelated to the technology or to finance, he says.

 

Stellaris, another player in this field, use small lenses to concentrate the light; from Mass High Tech:

By using small lenses, about 6 millimeters high, that concentrate light onto narrow strips of thin-film photovoltaic material, Stellaris is able to create a solar module that uses less photovoltaic material and is able concentrate sunlight at a ratio between 2-to-1 and 3-to-1 [...].
The lens technology is based on non-imaging optics, which gives its glazing material unique aesthetic properties, something Paull believes will help penetrate the building and architectural market, integrated with hard materials like industrial curtains or shingles.
“You can actually see through the glazing, as the energy is being integrated. It’s like a hologram,” he said.

In mid-2006, Kyosemi Corp. plans to begin full-scale mass production of its Sphelar spherical micro solar cell at its Eniwa Operation in Eniwa City, Hokkaido, Japan. While existing planar solar cells [...]]]> Kyosemi Corporation is developing solar cells consisting of 1mm spheres on a flexible substrate.
More information on the Sphelar solar cells: production process, main features, overview (PDF):

In mid-2006, Kyosemi Corp. plans to begin full-scale mass production of its Sphelar spherical micro solar cell at its Eniwa Operation in Eniwa City, Hokkaido, Japan.
While existing planar solar cells can take light only from their elevation surface, the Sphelar cell allows light to reach its cells from all directions because it has a spherical surface, providing a high level of photoelectric conversion efficiency. [...]
The company uses conditions of microgravity to form the Sphelar cells from molten silicon. Surface tension causes the silicon to take on a nearly perfect spherical shape. Due to segregation effects gained during the solidification process, single crystal silicon with a purity of 99.9999 percent can be obtained. The pn junctions are created using an n-plus diffusion process. Silver paste is used to attach electrodes. The product is finished with a coat of reflection film. [...]
If a Sphelar cell is encapsulated in acrylic resin, it can be turned into Flexible Sphelar sheet, a thin solar cell module whose shape can flexibly be changed into, say, a crescent or a curved form.
A module made with a series of Sphelar cells connected in parallel on silicone resin achieves a photo electric conversion efficiency of 19 percent.

See also this earlier article (”Spherical Solar Cells Solve Issue of 3-D Sunlight Reception”, 2003).

Founded in 2001, Konarka has steadily expanded its presence. Previous funding in Konarka—$60 million since 2001—has allowed the company to make considerable advances in its photovoltaic technology, while continuing to strengthen its intellectual property (IP) position. In 2004, Konarka acquired Siemens AG’s organic photovoltaic research activities, as [...]]]> Details here, including a bit more info on Konarka:

Founded in 2001, Konarka has steadily expanded its presence. Previous funding in Konarka—$60 million since 2001—has allowed the company to make considerable advances in its photovoltaic technology, while continuing to strengthen its intellectual property (IP) position. In 2004, Konarka acquired Siemens AG’s organic photovoltaic research activities, as well as its renowned scientific team. The Company also expanded and strengthened its European presence with the opening of a new center of operations, including research labs in Germany, and through a scale-up partnership with LEONARD KURZ GmbH & CO. KG. KURZ is a recognized leader in printing technology, with nine plant locations in Europe, the U.S. and the Pacific.