Power From Solar

Three student housing communities will be powered with solar power thanks to an agreement between Campus Crest Communities, a developer of student housing, and SolarCity, a provider of alternative energy. The student communities are located in Greeley (Colorado), Flagstaff (Arizona) and Las Cruces (New Mexico). They will be fitted with more than 9,000 solar panels.

The panels will generate more than 2.3 million kilowatt-hours of renewable energy annually, or 50 percent of the communities’ energy needs. They will help offset more than 80 million pounds of annual carbon dioxide emissions, the equivalent of taking approximately 7,000 cars off the road for a year.

“Sustainable living is central to our company philosophy and business practices, and we are pleased to find that our residents are equally as passionate about the concept. Shifting consumption towards clean energy will further our mission to be a leader in regenerative practices by using renewable sources to limit carbon emissions and reduce overall energy costs, which in turn allows us to provide our residents with cleaner, more energy efficient housing,” said Ted W. Rollins, Co-founder and Chief Executive Officer of Campus Crest.

Article by Antonio Pasolini, a Brazilian writer and video art curator based in London, UK. He holds a BA in journalism and an MA in film and television.

Article source: http://blog.cleantechies.com/2012/05/18/student-accommodations-to-be-powered-with-solar-energy/

Saudi Arabia, the world’s oil king, is looking to become the king of another resource:  solar power.

The Middle Eastern Kingdom has announced a plan to generate 40,000 megawatts, one-third of its power, from solar energy by 2032.  Saudi Arabian officials estimate this endeavour will cost US$109 billion to develop.

A consultant at King Abdullah City for Atomic and Renewable Energy said this goal will not only save roughly 520,000 barrels of oil per day over the next two decades, but also will diversify the nation’s domestic energy portfolio an create a sustainable solar energy sector.

Due to its geographic location, Saudia Arabia has great potential to develop solar energy.  At a recent conference, Shafiq Rahman, a researcher at King Fahd University of Petroleum and Minerals highlighted the potential for the country to become an exporter of solar power due to its abundant resources. 

Importing renewable energy is something energy starved nations could increasingly rely on.  This growing possibility, for example, has led the European Union to collaborate on the creation of North Africa’s immense Desertec solar project.

Currently Saudi Arabia has only 3 MW of installed solar power.

Read the full story at Solar PV Investor: Saudi Arabia, The Land of Plenty for Solar

Image credit: Bakar_88 via Flickr

Article source: http://feedproxy.google.com/~r/eboom_solar/~3/dwNL1vtiUBc/saudi-arabias-109-billion-plan-will-make-it-worlds-solar-giant

(16/05/2012)

SKF has launched the SKF BeyondZero portfolio which enables SKF customers to reduce their own environmental impact. The environmental improvements provided by solutions within the SKF BeyondZero portfolio are validated through a life cycle assessment methodology developed by SKF sustainability engineers. Results will be reviewed yearly by KPMG.

“The SKF BeyondZero portfolio is a major step for SKF in our development of solutions with reduced environmental impact for our customers. SKF products, solutions and services from our five technology platforms are already improving performance for our customers and enabling them to be more efficient,” says Tom Johnstone, SKF President and CEO. “The launch of these special BeyondZero portfolio solutions shows how further additional energy savings can be achieved and measured in specific applications. The BeyondZero portfolio fully complements and supports the existing range SKF offers for our customers.”

SKF’s customers in all segments and industries are increasingly driven to reduce environmental impact from their own products, services and processes. The SKF BeyondZero portfolio enables SKF customers to improve their own environmental performance. In 2011, SKF estimates the BeyondZero portfolio represented SEK 2.5 billion of sales. The goal is to reach SEK 10 billion by 2016.

“The irony for business is that where once we worried about our impact on the world around us, today the state of the world increasingly impacts the way we do business.
Population growth, energy and water scarcity are just a few of the global megatrends affecting us. Leading corporations recognize that there is value and opportunity in looking beyond the next quarter’s results, where anticipating societal trends and innovation can help satisfy the needs of both the client and the environment,” says Barend van Bergen, Head of KPMG’s Global Center for Excellence for Climate Change Sustainability.

Products currently included in the SKF BeyondZero portfolio are:

Automotive Market
 SKF Bus Door Actuator: With a reduced energy consumption of 80-90%, city buses using SKF actuators for operating the doors instead of pneumatic actuators saves 1.9 tonnes CO2 /year.
 SKF Low Weight Hub Bearing Unit reduces 0.25 g CO2 per km in a light commercial vehicle with four SKF Low Weight Hub Bearing Units. When based on an annual mileage of 14,500 km, the saving is 3.6 kg CO2 per year. Put another way, if one million cars used this solution the yearly reduction of CO2 would be 3,600 tonnes.
 SKF Rotor Positioning Bearing it is an integral component of Stop-Start systems for micro-hybrid vehicles. In dense urban traffic, Stop-Start can reduce fuel consumption and CO2 emissions up to 15%. Based on an annual mileage of 14,500 km, this solution saves 75 kg CO2 per year.
 SKF Low Friction Engine Seal reduces friction by up to 55%. When installed in a gasoline fueled engine it provides a CO2 savings of over 1 g per kilometre. Based on an annual mileage of 14,500km, this equates to a reduction of 14.5 kg/ CO2 per year. If one million cars were equipped with the SKF solution the reduction would be 14,500 tonnes of CO2 per year.
 SKF StopGo for two-wheelers reduces CO2 emissions by 5g per kilometre.
With an annual mileage of 7875 km, this equates to a reduction of 36 kg/CO2E per year. If one million motorcycles were equipped with the SKF solution the reduction would be 36,000 tonnes of CO2 per year.

Industrial Market
 SKF ConRo for the steel industry reduces an estimated average of 1.5 tonnes CO2 per roll line per year. In a normal-sized continuous steel casting machine with 400 roll lines, this means an annual CO2 reduction of approximately 600 tonnes.
 SKF Energy Monitoring Service – Pump Systems recently helped an SKF customer within the pulp and paper industry identify a reduction of its annual electricity demand by up to 2,000MW which equates to more than 1,500 tonnes* of CO2 per year.
 SKF CASM electric cylinders helped Indian Textiles, an SKF customer to reduce their energy use of one printing machine by an estimated 7MWh per year. This reduction translates into a CO2 savings of 5.3 tonnes* per year for only one machine.
 SKF Solar Linear Actuator – CASD-60 contributes to the reduction of CO2 emissions by increasing the energy production from one rigid solar panel by 5.8 MWh/year. This equates to a reduction per solution of 4.4 tonnes* CO2/year. On average, a 15% increase in power generation can be anticipated in comparison to rigid PV solar panel systems.
 SKF E2 Deep Groove Ball Bearing: Electric motor-driven systems (EMDS) consume more than 40% of global electricity production according to the International Energy Agency (Walking the Torque, 2011). If all new 1-50 HP motors were equipped with SKF E2 DGBB bearings instead of the standard (SKF) design, 290,000 tonnes of CO2 emissions would be avoided.
 SKF Nautilus bearing for the wind energy segment: A 3 MW wind turbine operating in a typical on-shore installation can produce 9 GWh renewable energy/year displacing around 6,700 tonnes of CO2. The Nautilus and other SKF products and solutions for the wind segment help make this possible.

Certain technologies or sectors are included in the portfolio because it is broadly acknowledged that they displace or replace more environmentally damaging infrastructure or equipment. Accordingly, SKF products, solutions and services provided to wind, solar, tidal power and electric vehicles are automatically included in the portfolio. For more information on the BeyondZero portfolio, visit: beyondzero.com

* Using a world power grid mix CO2 factor of 0.749 kg CO2/kWh

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Related categories:

 Carbon trading 

 Eco-friendly Power generation 

 Solar power and photovoltaics 

 Wave and tidal power 

 Wind power 

Article source: http://www.solarnewsportal.com/solar_article10963.html

San Diego, CA (PRWEB) May 15, 2012 San Diego solar panel provider Solaire Energy Systems is proud to announce its April 2012 promotion to Elite Dealer status by leading solar panel manufacturer SunPower. Recognized industry-wide for its quality, efficient energy production, and extreme durability, SunPower awards Elite status to its highest level of solar panel dealers.

In December of 2011, Solaire was named the #1 SunPower dealer in San Diego since partnering with SunPower – and their consistent quality installation of solar energy systems from SunPower has fueled their continued success. The “Elite Dealer” status is awarded to distributors who adhere to a strict set of performance standards set in place by SunPower and designed to ensure that those companies offer an extremely high level of customer service and product expertise. Elite Dealers must also complete a training program, and their installations are inspected regularly by SunPower representatives to ensure that quality standards are being met. Elite Dealers must also reach a consistent customer satisfaction score of above 90 percent.

“Solaire Energy Systems is very excited that our commitment to superior workmanship and dedication to customer service is being recognized within the solar community,” says Trey McCann, Solaire’s Chief Operations Officer. “We are excited to continue providing our customers with an excellent product at a great price.”

Solar panel systems produced by SunPower are proven in independent third-party studies to produce up to 50 percent more power per unit than conventional solar panels. They can also provide up to 100 percent more energy per unit than thin-film solar panels, making them one of the most efficient choices on the solar market. In addition to their extreme energy production capabilities and long-lasting durability, SunPower panels feature a sleek black design that matches any color of residential rooftop without looking awkward or unpleasant.

A study by the U.S. Department of Energy showed that installing a solar energy system increases the sale value of a home by an average of $17,000 – an enormous benefit to homeowners given the difficult 2012 housing market. With a quality solar panel San Diego residents can increase the value of their home, reduce or eliminate their energy bills, and contribute to environmental efforts in an affordable and forward-thinking way.

About Solaire Energy Systems
Solaire Energy Systems is a leading San Diego solar panel provider specializing in solar panel installation, high-efficiency HVAC, solar hot water systems, and solar pool heating systems. Their recognition as an Elite SunPower dealer reflects their commitment to quality and customer service. For more information, visit http://www.gosolaire.com.

Article source: http://feedproxy.google.com/~r/blogspot/NrBn/~3/ZUbYnPKtzwI/san-diego-solar-company-solaire-awarded.html

ScienceDaily (May 13, 2012) — Using tiny solar-panel-like cells surgically placed underneath the retina, scientists at the Stanford University School of Medicine have devised a system that may someday restore sight to people who have lost vision because of certain types of degenerative eye diseases.

This device — a new type of retinal prosthesis — involves a specially designed pair of goggles, which are equipped with a miniature camera and a pocket PC that is designed to process the visual data stream. The resulting images would be displayed on a liquid crystal microdisplay embedded in the goggles, similar to what’s used in video goggles for gaming. Unlike the regular video goggles, though, the images would be beamed from the LCD using laser pulses of near-infrared light to a photovoltaic silicon chip — one-third as thin as a strand of hair — implanted beneath the retina.

Electric currents from the photodiodes on the chip would then trigger signals in the retina, which then flow to the brain, enabling a patient to regain vision.

A study, to be published online May 13 in Nature Photonics, discusses how scientists tested the photovoltaic stimulation using the prosthetic device’s diode arrays in rat retinas in vitro and how they elicited electric responses, which are widely accepted indicators of visual activity, from retinal cells . The scientists are now testing the system in live rats, taking both physiological and behavioral measurements, and are hoping to find a sponsor to support tests in humans.

“It works like the solar panels on your roof, converting light into electric current,” said Daniel Palanker, PhD, associate professor of ophthalmology and one of the paper’s senior authors. “But instead of the current flowing to your refrigerator, it flows into your retina.” Palanker is also a member of the Hansen Experimental Physics Laboratory at Stanford and of the interdisciplinary Stanford research program, Bio-X. The study’s other senior author is Alexander Sher, PhD, of the Santa Cruz Institute of Particle Physics at UC Santa Cruz; its co-first authors are Keith Mathieson, PhD, a visiting scholar in Palanker’s lab, and James Loudin, PhD, a postdoctoral scholar. Palanker and Loudin jointly conceived and designed the prosthesis system and the photovoltaic arrays.

There are several other retinal prostheses being developed, and at least two of them are in clinical trials. A device made by the Los Angeles-based company Second Sight was approved in April for use in Europe, and another prosthesis-maker, a German company called Retina Implant AG, announced earlier this month results from its clinical testing in Europe.

Unlike these other devices — which require coils, cables or antennas inside the eye to deliver power and information to the retinal implant — the Stanford device uses near-infrared light to transmit images, thereby avoiding any need for wires and cables, and making the device thin and easily implantable.

“The current implants are very bulky, and the surgery to place the intraocular wiring for receiving, processing and power is difficult,” Palanker said. The device developed by his team, he noted, has virtually all of the hardware incorporated externally into the goggles. “The surgeon needs only to create a small pocket beneath the retina and then slip the photovoltaic cells inside it.” What’s more, one can tile these photovoltaic cells in larger numbers inside the eye to provide a wider field of view than the other systems can offer, he added.

Stanford University holds patents on two technologies used in the system, and Palanker and colleagues would receive royalties from the licensing of these patents.

The proposed prosthesis is intended to help people suffering from retinal degenerative diseases, such as age-related macular degeneration and retinitis pigmentosa. The former is the foremost cause of vision loss in North America, and the latter causes an estimated 1.5 million people worldwide to lose sight, according to the nonprofit group Foundation Fighting Blindness. In these diseases, the retina’s photoreceptor cells slowly degenerate, ultimately leading to blindness. But the inner retinal neurons that normally transmit signals from the photoreceptors to the brain are largely unscathed. Retinal prostheses are based on the idea that there are other ways to stimulate those neurons.

The Stanford device uses near-infrared light, which has longer wavelength than normal visible light. It’s necessary to use such an approach because people blinded by retinal degenerative diseases still have photoreceptor cells, which continue to be sensitive to visible light. “To make this work, we have to deliver a lot more light than normal vision would require,” said Palanker. “And if we used visible light, it would be painfully bright.” Near-infrared light isn’t visible to the naked eye, though it is “visible” to the diodes that are implanted as part of this prosthetic system, he said.

Palanker explained what he’s done by comparing the eye to camera, in which the retina is the film or the digital chip, and each photoreceptor is a pixel. “In our model we replace those photoreceptors with photosensitive diodes,” he said. “Every pixel is like a little solar cell; you send light, then you get current and that current stimulates neurons in the inner nuclear layer of the retina.” That, in turn, should have a cascade effect, activating the ganglion cells on the outer layer of the retina, which send the visual information to the brain that allows us to see.

For this study, Palanker and his team fabricated a chip about the size of a pencil point that contains hundreds of these light-sensitive diodes. To test how these chips responded, the researchers used retinas from both normal rats and blind rats that serve as models of retinal degenerative disease. The scientists placed an array of photodiodes beneath the retinas and placed a multi-electrode array above the layer of ganglion cells to gauge their activity. The scientists then sent pulses of light, both visible and near-infrared, to produce electric current in the photodiodes and measured the response in the outer layer of the retinas.

In the normal rats, the ganglions were stimulated, as expected, by the normal visible light, but they also presented a similar response to the near-infrared light: That’s confirmation that the diodes were triggering neural activity.

In the degenerative rat retinas, the normal light elicited little response, but the near-infrared light prompted strong spikes in activity roughly similar to what occurred in the normal rat retinas. “They didn’t respond to normal light, but they did to infrared,” said Palanker. “This way the sight is restored with our system.” He noted that the degenerated rat retinas required greater amounts of near-infrared light to achieve the same level of activity as the normal rat retinas.

While there was concern that exposure to such doses of near-infrared light could cause the tissue to heat up, the study found that the irradiation was still one-hundredth of the established ocular safety limit.

Since completing the study, Palanker and his colleagues have implanted the photodiodes in rats’ eyes and been observing and measuring their effect for the last six months. He said preliminary data indicates that the visual signals are reaching the brain in normal and in blind rats, though the study is still under way.

While this and other devices could help people to regain some sight, the current technologies do not allow people to see color, and the resulting vision is far from normal, Palanker said.

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The above story is reprinted from materials provided by Stanford University Medical Center. The original article was written by Jonathan Rabinovitz.

Note: Materials may be edited for content and length. For further information, please contact the source cited above.

Journal Reference:

1. Keith Mathieson, James Loudin, Georges Goetz, Philip Huie, Lele Wang, Theodore I. Kamins, Ludwig Galambos, Richard Smith, James S. Harris, Alexander Sher, Daniel Palanker. Photovoltaic retinal prosthesis with high pixel density. Nature Photonics, 2012; DOI: 10.1038/nphoton.2012.104

Note: If no author is given, the source is cited instead.

Disclaimer: This article is not intended to provide medical advice, diagnosis or treatment. Views expressed here do not necessarily reflect those of ScienceDaily or its staff.

Article source: http://www.sciencedaily.com/releases/2012/05/120513144617.htm

Date: 2012-05-11, 10:46AM EDT
Reply to: 8tqm9-3009231240@job.craigslist.org

Territory Manager — Retail Sales — New York Metro

Sunrun is looking for highly motivated team members to join our Home
Depot sales program in the New York metro area. You will be part of the
nation’s largest residential solar power company, contributing to a
high-performing sales team in a fast-paced, dynamic environment. In
this position you will be on the front lines, revolutionizing the way
American homeowners power their homes.

Territory Managers will be driven, energetic, responsible,
high-integrity, and entrepreneurial. You will manage a territory of
Home Depot stores — solving day-to-day issues, training and educating
associates, achieving sales targets, and delivering the highest level of
service to the Home Depot. This position is full-time and is based in
the New York metro area.

To apply please send an email introduction and resume to http://newton.newtonsoftware.com/career/SubmitResume.action?id=8a42a12b372c0ea701373bdbba8e1826source=Craigslist

Responsibilities
• Engage stores to drive sales and achieve territory sales goals
• Train, motivate, and educate store associates
• Act as full-service point-of-contact for Home Depot’s solar program
• Track and report on performance, activity, and opportunities
• Consistently deliver a monthly sales target

Qualifications and Key Attributes
• Positive, high-energy, thrives on working with people
• Exceptional communication and interpersonal skills
• Creative, resourceful, organized, detail-oriented
• Demonstrated ability as self-starter, leader, teammate
• Comfortable with reporting tools and metrics
• Retail experience and comfort with B2B and B2C sales are preferred
• Territory requires travel within New York metro (New Jersey, New York)

• Location: New York Metro
• Compensation:  Competitive base pay and incentive based on results

Article source: http://www.solarpowerbuzzmedia.com/2012/05/jobs-in-solar-territory-manager-retail.html

ScienceDaily (May 10, 2012) — The photovoltaics industry is booming, and the market for solar farms is growing quickly all over the world. Yet, the task of planning PV power plants to make them as efficient as possible is far from trivial. Fraunhofer researchers, working with Siemens Energy Photovoltaics, have developed software that simplifies conceptual design.

The share of renewable energies in the overall energy mix is rising rapidly worldwide. With three-figure growth rates, photovoltaics (PV) play a major role. According to market research organizations, the PV market grew by 139 percent in the year 2010. Germany is among the world’s leaders in this technology that uses solar cells to convert sunlight straight into electrical energy. Yet the task of planning large-scale PV power plants spanning several square kilometers is a complex one. With customer specifications, regulations and government subsidy programs to consider, designers must also account for numerous other factors including weather, climate, topography and location. These factors, in turn, influence the selection and placement of the individual components which include the PV arrays with their solar modules, inverters and wiring, not to mention access roads. Until now, engineers have designed solar power plants using CAD programs, with every layout and every variation painstakingly generated separately. This is a very time-consuming approach. To improve a planned power plant in terms of certain criteria, or to compare different concepts with one another, oftentimes the entire planning process has to be repeated.

Several hundred plant designs at the push of a button

In the future, this approach will be improved considerably: researchers at the Fraunhofer Institute for Industrial Mathematics ITWM in Kaiserslautern, in collaboration with Siemens Energy Photovoltaics, have developed a new planning software that makes it possible to build solar power plants better and more quickly. “Our algorithms programmed exclusively for the Siemens PVplanet (PV Plant Engineering Toolbox) software provide engineers with several hundred different plant designs in a single operation. It takes less than a minute of computation time,” ITWM researcher Dr. Ingmar Schüle points out. The only user inputs are parameters such as the topography of the construction site and the module and inverter types that will be used. The user can also change a number of parameters – such as the orientation, spacing and inclination of the solar arrays – to study the impact on the quality of the planning result.

Cost estimates and income calculations included

To evaluate the designed PV power plants, an income calculation is performed that includes a simulation of the weather in the region in question, the course of the sun throughout the year and the physical module performance including shading effects. With the results of this computation and an estimate of the investment and operating costs, the planning tool can come up with a figure for the LCOE (levelized cost of energy). By comparing the plant with a large number of similar configurations, the planners can investigate the sensitivity of the various parameters to find the right solution from a large array of options. “The software assists the expert with decisionmaking and helps with the design of the best possible PV power plant for the site involved.

Which one is ‘best’ depends on a number of aspects – from the customer’s objectives to the site and environmental conditions, but also on the financing concept and the financial incentives for photovoltaics in the target region. All of these criteria are taken into account.” Schüle points out. Dr. Martin Bischoff, project manager at Siemens AG, Energy Sector, is also convinced of this approach: “Aside savings, more than anything else the planning tool provides an overview of the scope for optimization. This provides the best possible support for planning the most cost-efficient systems. There has been no other planning software with this scope or level of detail until now.” Interested individuals can get an impression of the successful teamwork between ITWM and Siemens Energy Photovoltaics at the Intersolar Europe trade fair in Munich, June 13-15, 2012: the software celebrates its public premiere at the Siemens booth.

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Story Source:

The above story is reprinted from materials provided by Fraunhofer-Gesellschaft, via AlphaGalileo.

Note: Materials may be edited for content and length. For further information, please contact the source cited above.

Note: If no author is given, the source is cited instead.

Disclaimer: Views expressed in this article do not necessarily reflect those of ScienceDaily or its staff.

Article source: http://www.sciencedaily.com/releases/2012/05/120510100048.htm

FARMINGTON, Conn., May 10, 2012 /PRNewswire-iReach/ — Global Information Inc. is pleased to announce two significant new renewable energy market forecasts in the growing field of organic photovoltaics (OPV).

Organic Photovoltaics Technologies, Players and Forecasts 2012-2022
New organic photovoltaics market research, Organic Photovoltaics Technologies, Players and Forecasts 2012-2022 by IDTechEx, estimates that the organic photovoltaics (OPV) market will explode by over 1300% by 2022, from a value of $4.6 million today up to over $630 million in just 10 years. This report develops technology roadmaps and guidelines which forecast improvements in module efficiency, lifetime and costs over the next decade, to provide a practical insight into how the technology is likely to evolve.

In addition to providing an excellent form factor, OPVs combine good performance under indoor lighting conditions with low capital expenditure, and potentially very low energy production costs using printable plastics. The market growth will be predominantly driven by electronics in apparel, posters and PoP smart labels, and off-grid developing world applications. Despite tremendous growth potential, OPVs will nonetheless remain a small player on the greater PV scene, obtaining total market shares 1.5% over the next decade.

An Executive Summary for this report and a free sample of the full document are available at http://www.giiresearch.com/report/ix240033-organic-photovoltaics-technologies-players.html

Opportunities in the Organic Photovoltaics Market – 2012
The critical question of whether performance improvements are likely to help grow addressable markets for OPV or the OPV market’s growth will continue to underperform is further addressed in NanoMarkets’ new organic photovoltaics market research report Opportunities in the Organic Photovoltaics Market 2012.

This report examines the potential for OPV in the building-integrated and/or building-applied PV (BIPV/BAPV) sector in light of strong competition from other emerging PV technologies, particularly from dye-sensitize cell (DSC) and copper-indium-gallium-(di)selenide CIGS PV.

The OPV device markets are considered in light of the various applications they are targeted toward, which include off-grid portable charging, solar shades, conventional panels and BIPV (including flexible BIPV, BIPV glass, and building-applied PV (BAPV), etc.

An Executive Summary for this report and a free sample of the full document are available at http://www.giiresearch.com/report/nan238145-opportunities-organic-photovoltaics-market-2012.html

About Global Information Inc. Global Information (GII) (http://www.giiresearch.com) is an information service company partnering with over 300 research companies around the world. Global Information has been in the business of distributing technical and market research for more than 25 years. Expanded from its original headquarters in Japan, Global Information now has offices in Korea, Taiwan, Singapore, Europe and the United States

Article source: http://feedproxy.google.com/~r/blogspot/NrBn/~3/8Z5uosjlzsE/organic-photovoltaics-clean-energy.html

ScienceDaily (May 10, 2012) — Researchers at the University of Turku believe that flexible, lightweight and inexpensive dyes could be used to harvest the power of the sun rather than our relying on costly and fragile semiconductor solar panel that use crystalline silicon.

Writing in the International Journal of Technology, Policy and Management this month, Jongyun Moon and colleagues Aulis Tuominen and Arho Suominen, explain that dye-sensitised solar cells (DSCs) are set to become a ubiquitous source of energy without the complex and expensive clean-room manufacturing processes associated with current solar panels. They point out that the rapid increase in research into novel solar energy conversion technology looks set to revolutionise the industry making electricity generation accessible to all without government or other subsidies.

Solar power is an essential part of the green energy mix, but adoption has been limited in many parts of the world where government subsidies and financial incentives have not been in place. However, as part of a sustainable approach to electricity generation, it offers a clear view of a future in which domestic supply relies less and less on grid power systems or else provides a localised grid for remote places, particularly in sunny climes. Photovoltaic solar cells based on poly-crystalline silicon are the most commonly used devices, having first been used as space satellite technology back in the 1950s and 1960s.

In a DSC, sunlight hits a layer of the white pigment titanium dioxide, the solar energy absorbed then sucks electrons from dye molecules in a layer beneath this coating, thus generating a flow of electrons and producing a current.

However, Moon and colleagues suggest that despite the maturity of the silicon technology DSCs could ultimately displace it simply because they are easier and cheaper to manufacture. That said, current DSCs are less efficient than silicon devices and so much development work remains to be undertaken over the coming years.

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The above story is reprinted from materials provided by Inderscience, via AlphaGalileo.

Note: Materials may be edited for content and length. For further information, please contact the source cited above.

Journal Reference:

1. Moon et al. Forecasting a change in technology: Are Dye-sensitised Solar Cells a source of ubiquitous energy? International Journal of Technology, Policy and Management, 2012, 12, 177-194

Note: If no author is given, the source is cited instead.

Disclaimer: Views expressed in this article do not necessarily reflect those of ScienceDaily or its staff.

Article source: http://www.sciencedaily.com/releases/2012/05/120510113719.htm