graphene_manchester

The heterostructures is based on 2D atomic crystals for photovoltaic applications.
Image: University of Manchester

Researchers from the University of Manchester in conjunction with the National University of Singapore have discovered an exciting new development with the wonder material graphene.

The researchers have been able to combine graphene with other one-atom thick materials to create the next generation of solar cells and optoelectronic devices.

With this, they have been able to demonstrate how multi-layered heterostructures in a three-dimensional stack can produce an exciting physical phenomenon exploring new electronic devices.

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45.7% Efficiency for Concentrator Solar Cell

This achievement represents one of the highest photovoltaic research cell efficiencies achieved across all types of solar cells.Credit: NREL (Click to enlarge)

This achievement represents one of the highest photovoltaic research cell efficiencies achieved across all types of solar cells.
Credit: NREL (Click to enlarge)

Improvements in solar power are being developed all around the world, with scientist and researchers continuously attempting to apply electrochemistry and other sciences to solar cells in order to improve efficiency. Recently, the National Renewable Energy Laboratory (NREL) has reported one of the highest photovoltaic cell efficiencies achieved across all types of solar cells.

Researchers at the NREL have demonstrated a 45.7 percent conversion efficiency for a four-junction solar cell at 234 suns concentration.

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Innovation in Spray-on Solar Power

The SparyLD system developed by University of Toronto researchers can spray colloidal quantum dots onto flexible surfaces.Credit: University of Toronto

The SparyLD system developed by University of Toronto researchers can spray colloidal quantum dots onto flexible surfaces.
Credit: University of Toronto

Teams of scientists from around the world have been working on a way to produce spray-on solar cells for some time now. Recently, a team from the University of Toronto Faculty of Applied Science & Engineering has moved to the forefront of the race due to their latest breakthrough involving a new method for spraying solar cells onto flexible surfaces.

The prototype applies colloidal quantum dots via spray. These dots are a type of nanotechnology material that are light-sensitive.

This from Gizmag:

In such spray on solar cells, quantum dots would act as the absorbing photovoltaic material. Because they have a band gap that can be tuned by altering the size of their nanoparticles, they can be made to soak up different parts of the solar spectrum. This could prove particularly valuable if they were to be used in multi-junction solar cells, where dots small and large could sit alongside each other to widen the cells’ energy harvesting potential.

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Old Blu-Ray Discs to Make Better Solar Panels

An interdisciplinary team from the McCormick School of Engineering and Applied Science discovered that using the data storage pattern from a Blu-ray disc improves solar cell performance and that video content doesn’t matter.Credit: Northwestern University

An interdisciplinary team from the McCormick School of Engineering and Applied Science discovered that using the data storage pattern from a Blu-ray disc improves solar cell performance and that video content doesn’t matter.
Credit: Northwestern University

Since its launch, the Blu-ray disc has been promoted as the bigger, better, and more impressive way to view movies at home. But researchers from Northwestern University are now telling us that Blu-ray discs are good for more than just giving us a better home viewing experience.

An interdisciplinary team from the McCormick School of Engineering and Applied Science at Northwestern University has published research stating that Blu-ray discs can be used to improve the performance of solar cells.

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First Solar-Powered Bike Lane in Netherlands

SolaRoad coverts sunlight on the road surface into electricity: the road network works as an inexhaustible source of green power.Credit: SolaRoad

SolaRoad converts sunlight on the road surface into electricity: the road network works as an inexhaustible source of green power.
Credit: SolaRoad

A solar-powered cycle path – called SolaRoad – has been unveiled in the Netherlands. The path can generate enough electricity to power three households, reports BBC.

The new path has been installed in Kormmenie, which is 25 kilometers from Amsterdam. While the path is currently 70 meters long, it will be extended to 100 meters by 2016.

Dr. Sten de Wit from SolaRoad believes that this is just the beginning for solar-powered paths. Dr. de Wit foresees solar roads eventually being used to power the electric vehicles that use them, similar to Dutch developer Heijmans and designer Daan Roosegaard in their “smart highway.”

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The ECS Journal of Solid State Science and Technology (JSS) is one of the newest peer-reviewed journals from ECS launched in 2012.

The ECS Journal of Solid State Science and Technology (JSS) is one of the newest peer-reviewed journals from ECS launched in 2012.

Printing technologies in an atmospheric environment offer the potential for low-cost and materials-efficient alternatives for manufacturing electronics and energy devices such as luminescent displays, thin film transistors, sensors, thin film photovoltaics, fuel cells, capacitors, and batteries.

This focus issue will cover state-of-the-art efforts that address a variety of approaches to printable functional materials and devices.

Topics of interest include but are not limited to:

  • Printable functional materials: metals; organic conductors; organic and inorganic semiconductors; and more
  • Functional printed devices: RFID tags and antenna; thin film transistors; solar cells; and more
  • Advances in printing and conversion processes: ink chemistry; ink rheology; printing and drying process; and more
  • Advances in conventional and emerging printing techniques: inkjet printing; aerosol printing; flexographic printing; and more

Find out more!

Deadline for submission of manuscripts is November 30, 2014.

Please submit manuscripts here.

“Stella” is the name on every climate-cautious, pollution-loathing environmentalist’s lips.

Who is Stella? Well, she’s a car.

She may not be “pretty” by conventional standards, but Stella is the first family car powered by solar energy. The car – driven by a team of students from Eindhoven University of Technology – has just finished its road trip from Los Angeles to San Francisco, fueled solely by the California sunshine.

While the car is capable of traveling 500 miles (800km) on a single charge and can clock up to 80 miles per hour, there is still one pressing question on everyone’s mind – who will drive it?

“Do you want it in your daily life? Would you want to take it to get groceries?” asked one of Stella’s drivers, Jordy de Renet, in an interview with Popular Science.

The car’s strange shape stems from a compromise for aerodynamics and allowing comfort for at least two people. Also, the wedge-shaped vehicle’s flat surface allows for more solar cell coverage.

This from Popular Science:

Stella is CO2-neutral and the first energy-positive car in the world. The solar array charges while the car is in motion as well as when it is parked. “We get more energy out of the car than is needed to drive it,” said de Renet. That power, as much as twice what the car uses, can be returned to the grid.

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The researchers discovered that two flat semiconductor materials can be connected edge-to-edge with crystalline perfection.Credit: University of Washington

The researchers discovered that two flat semiconductor materials can be connected edge-to-edge with crystalline perfection.
Credit: University of Washington

Current member of ECS, Xiaodong Xu, has made a huge contribution to the field of electrochemical science with the creation of atomically seamless, thinnest-possible semiconductor junctions.

Xu, along with the scientists at the University of Washington, believe their semiconductor – coming in at only three atoms thick – is the most slender possible, a new class of nanoscale materials.

This from the University of Washington:

The University of Washington researchers have demonstrated that two of these single-layer semiconductor materials can be connected in an atomically seamless fashion known as a heterojunction. This result could be the basis for next-generation flexible and transparent computing, better light-emitting diodes, or LEDs, and solar technologies.

Read the full article here.

“Our experimental demonstration of such junctions between two-dimensional materials should enable new kinds of transistors, LEDs, nanolasers, and solar cells to be developed for highly integrated electronic and optical circuits within a single atomic plane,” Xu said.

The research was published online this week in Nature Materials.

Find more research from Xu published in our Digital Library.

Lead-acid car batteries

According to engineers at MIT, we can recycle them to make long-lasting, low-cost solar panels. Credit: Christine Daniloff

The old lead-acid battery in your car may not be as useless or environmentally dangerous as was once thought. In fact, these batteries may be the answer to creating a cheap source of green energy.

According to engineers at MIT, old lead-acid batteries can be recycled and easily converted into long-lasting, low-cost solar panels. So far, the solar cells in the panels have yielded promising results – achieving over 19 percent efficiency in converting sunlight to useable electricity.

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Dye-sensitized socal cell

From: Perovskite Solar Cells: Rising, Last Advances, and Future Perspectives

This post went up the other day in our ECS Linkedin group:

Perovskite Solar Cells: Rising, Last Advances, and Future Perspectives

The progress made by emerging photovoltaic technologies in the last year has been outstanding. Important steps towards the realization of silicon-free solid-state solar cells with a real potential for commercialization were taken. In particular, a number of milestones have been achieved in the development of hybrid mesoscopic and thin-film solar cells based on the use of nanocrystals of organometal halide perovskites as the light absorbers. Under this approach, the power conversion efficiency (PCE) has been boosted from values around 6-8% (hold by metal chalcogenide solar cells) to over the 19%. Such a performance is now very close to the 25% of crystalline silicon solar cells, the leading commercial technology. But the most intriguing is that these breakthroughs have been achieved in devices entirely fabricated in the solid state, which, so far, had shown worse energy conversion abilities than their counterparts based on liquid electrolytes like dye-sensitized solar cells.  Read the rest.

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