Solar Energy
Sandia-developed solar cell technology reaches space
Somewhere among the glitter of the night sky is a small satellite powered by innovative, next-generation solar cell technology developed at Sandia National Laboratories.
mPower Technology’s DragonSCALES, consist of small, highly interconnected photovoltaic cells formerly known as solar glitter at Sandia. They are orbiting Earth for the first time on a Lynk Global Inc. satellite that supports direct connection to unmodified mobile phones. The satellite was launched this summer.
The technology is being evaluated as a potential solar power solution for the Lynk Global constellation fleet. Data collected will provide valuable feedback to validate the product’s performance in space.
“It’s been amazing to watch this technology emerge from the labs and become a product sought after by satellite companies and federal agencies,” said Mary Monson, Sandia’s senior manager of technology partnerships and business development.
The solar cell technology was developed at the labs to reduce the cost of creating solar technology and increase its efficiencies. mPower Technology, a small, New Mexico company, licensed the technology from Sandia and commercialized it as DragonSCALES. The interconnected cells are made of highly efficient silicon that can be meshed into any shape, size or form.
mPower executives say benefits of the technology include ease of installation and system integration. Development costs are lower than other solar technologies because microcells require little material to form well-controlled and highly efficient devices.
“This was the first launch of our innovative DragonSCALES product with Lynk Global, and we look forward to a successful on-orbit demonstration for their constellation,” said Kevin Hell, mPower Technology president and CEO. “With the rapidly increasing interest in our technology for a wide range of new space power missions, we expect many more launches in the near future.”
Aiming for the stars and a future lunar landing
Future projects may take the technology as far as the moon.
mPower and spacecraft systems company Honeybee Robotics Inc. were recently selected by NASA as one of five commercial teams to develop designs for deployable solar array systems to be used on the surface of the moon and one day as charging stations to recharge rovers, battery packs and other electrical equipment used by spacecraft and astronauts.
The teams’ designs must be maneuverable, fold into a volume of less than half a cubic meter and, if selected by NASA, the developed station would be dropped off by lunar rovers to supply power. The team is focused on a Honeybee concept called Lunar Array Mast and Power System, LAMPS, that incorporates DragonSCALES. The design will use some of the most cost-effective, lightest, large area extendable solar panels ever made, according to mPower.
Murat Okandan, mPower chief technology officer, said, “Some of the most exciting and challenging systems coming up have characteristics that are very similar to LAMPS, where cost-effective, large-scale deployment of power systems is going to be critical in being able to meet the mission needs and support the envisioned expansion of activity in orbit and for landed systems.”
Labs programs enabled technology to reach private sector
Sandia announced the development of solar glitter in 2009 after the solar cells were fabricated by researchers using technologies to fabricate microelectromechanical systems in Sandia’s Microsystems Engineering, Science and Applications facility, giving it the nickname MEPV for microsystem-enabled photovoltaics.
The original Sandia team continued to advance the technology through various projects sponsored by Sandia’s Laboratory Directed Research and Development program, the military and NASA. Today, some of the fabrication approaches pioneered by MEPV, such as oxide bonding, continue to be used for research involving semiconductors.
“DragonSCALES began as a Laboratory Directed Research and Development project in our lab over 12 years ago,” said Keith Ortiz, manager of the microelectromechanical systems technologies department. “Now, the technology is in space, and I’m looking forward to the next 12 years of development beyond Sandia.”
Okandan, one of the researchers who developed the technology, left Sandia through the Entrepreneurial Separation to Technology Transfer program and founded mPower. The program enables Sandia to transfer technology to the private sector by permitting employees to leave the labs to start up or expand tech companies. Entrepreneurs are guaranteed reinstatement for up to two years if they choose to return to Sandia.
In 2017, solar glitter was licensed to mPower. While the technology could be applied to a variety of devices of any shape, the company is focused on the space market and rapidly deployable, portable solar power systems.
“We couldn’t be prouder of the researchers who developed solar glitter and established a technology bound for space,” Monson said. “This is exactly the type of impact we are dedicated to at Sandia through our technology transfer programs. When technology leads to new companies, jobs and commercialization, it’s a win-win all around.”
Mini solar cells garner years of recognition
Solar glitter and DragonSCALES have received recognition through awards and news stories. In 2012 when the technology was new, Sandia received a prestigious R and D100 Award.
Following successful efforts to transfer the technology to mPower, Sandia and the company have been recognized multiple times by the Federal Laboratory Consortium. Earlier this year, the partnership received a national Excellence in Technology Transfer Award from the consortium for transforming space power and other commercial markets.
Solar investment outstrips all other power forms: IEA
by AFP Staff Writers
Paris (AFP) June 6, 2024
More money is pouring into solar power than all other electricity sources combined, with investments set to reach half a trillion dollars this year, the world’s top energy research body said Thursday.
The International Energy Agency (IEA) forecast in a report that global investment in clean energy this year will hit $2 trillion, twice the amount going to fossil fuels.
It said combined investment in renewable power and grids overtook the amount spent on fossil fuels for the first time in 2023.
“Clean energy investment is setting new records even in challenging economic conditions, highlighting the momentum behind the new global energy economy,” IEA executive director Fatih Birol said in a statement accompanying the agency’s annual World Energy Investment report.
Companies and governments worldwide are raising spending on clean energy production to reduce the carbon emissions from burning fossil fuels that are driving deadly climate change.
The report said improving supply chains and lower costs were driving up investment in forms of so-called clean energy, which include solar panels, wind turbines, electric cars and heat pumps, as well as nuclear power generation.
Combined investment in renewables and nuclear for electricity generation is now set to reach 10 times the amount going to fossil-fuel power, led by solar, with China investing the biggest share.
“More money is now going into solar PV (photovoltaic panels) than all other electricity generation technologies combined,” the report said.
Solar panel costs have decreased by 30 percent over the past two years and in 2024 “investment in solar PV is set to grow to $500 billion as falling module prices spur new investments.”
By comparison, global upstream oil and gas investment is expected to increase by seven percent in 2024 to reach $570 billion, following a similar rise in 2023.
The IEA warned however of “major imbalances and shortfalls in energy investment flows in many parts of the world” where clean energy projects remain prohibitively expensive.
Excluding renewable energy giant China, the $300 billion invested by emerging and developing economies remained “far below what is required to meet growing energy demand in many of these countries”.
“More must be done to ensure that investment reaches the places where it is needed most,” Birol said.
The IEA said that meeting medium-term global goals to reduce harmful carbon emissions would require investment in renewable power to be doubled worldwide by 2030.
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Atlas reveals solar energy potential in Germany
by Robert Schreiber
Berlin, Germany (SPX) Jun 06, 2024
Which roofs are suitable for solar panel installations? Where are photovoltaic systems already in place? How much output could be achieved with solar panel arrays at specific locations? A map developed by the German Aerospace Center (Deutsches Zentrum fur Luft- und Raumfahrt; DLR) provides the answers. DLR’s researchers used machine learning methods to process current aerial photographs and geodata, enabling them to determine solar energy potential for the entire stock in Germany of around 20 million buildings. Results for the whole country are publicly available at eosolar.dlr.de.
The Solar Atlas is being presented at ILA in Berlin, where DLR is showcasing its research and development work in aeronautics, space, energy, transport, digitalisation and security.
“Policy makers need precise information on the current inventory and growth potential in order to devise and implement effective strategies for expanding photovoltaic systems on roofs,” explains Anke Kaysser-Pyzalla, Chair of the DLR Executive Board.
“The satellite-derived information provided by DLR supports the energy transition and drives forward innovative products and business models. The DLR Solar Atlas shows how Earth observation can be used successfully for climate protection and the sustainable expansion of energy generation.”
Multiple terabytes of data evaluated
Within the framework of the EO Solar project, researchers from the DLR Earth Observation Center (EOC) are evaluating and combining several terabytes of data from various sources to outline the current situation in Germany. These include digital, distortion-free aerial photographs with a resolution of 20 centimetres and high-quality surface models with a resolution of one metre, provided by the Federal Agency for Cartography and Geodesy.
“To evaluate the current expansion potential for solar energy, we calculate the possible electrical output based on the hours of sunshine, radiation intensity, orientation of roof surfaces and shading from neighbouring buildings or vegetation,” says Annekatrin Metz-Marconcini, who heads the EO Solar project.
“DLR has also developed a process using artificial intelligence that enables us to identify roofs with existing solar panels anywhere in the world based on high-resolution remote sensing data. In Germany, we have included the Core Energy Market Data Register in the information that we use.” The Core Energy Market Data Register lists all registered German solar panel installations and is updated on a daily basis.
Rather than building models, EO Solar uses digital terrain models, including those generated with the help of aircraft and satellites. These models automatically take account of shading from trees and the surrounding area, and the process can be extended to countries that do not have building models. Other than the roofs of buildings, the solar energy potential of open spaces can also be calculated using the same methodology and then taken into account for planning purposes.
Solar potential identified for municipalities, districts and federal states
Existing solar panel registers for federal states, districts or municipalities often differ in the level of information included, may lack detail or be limited to certain areas. By contrast, the DLR Solar Atlas provides an up-to-date, systematic mapping of the whole of Germany and as such offers policy makers and planners alike a basis for promoting the targeted expansion of photovoltaic systems.
DLR researchers have already created a similar map for Austria as part of an ESA project. For data protection reasons, it is not possible to map solar expansion potential for individual buildings on a publicly available website in Germany, so the expansion potential is shown at municipal, district or federal state level. The publicly accessible website eosolar.dlr.de has recently been set up for this purpose.
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Some countries could meet electricity needs with floating solar panels, research shows
by Sophie Jenkins
London, UK (SPX) Jun 05, 2024
Floating solar photovoltaic (FPV) panels could supply all the electricity needs of some countries, according to new research. The study by Bangor and Lancaster Universities and the UK Centre for Ecology and Hydrology evaluated the global potential for low-carbon floating solar arrays. Researchers calculated daily electrical output from FPV on nearly 68,000 lakes and reservoirs worldwide, using climate data for each location.
The study focused on lakes and reservoirs likely to support floating solar technology, which are within 10 km of a population center, not in protected areas, and don’t dry up or freeze for more than six months each year. Researchers based their calculations on FPV covering 10% of surface areas, up to 30 km.
Potential annual electricity generation from FPV on these lakes is 1302 terawatt hours (TWh), about four times the UK’s total annual electricity demand. The findings are published in Nature Water.
FPV systems offer several advantages over land-based solar installations, including freeing up land for other uses and keeping panels cooler for better efficiency. There is also evidence for additional environmental benefits, such as reducing water evaporation and limiting algal blooms. However, further research is needed on FPV’s overall environmental impact, and deployment decisions should consider the intended function of water bodies and potential ecological impacts.
Lead author Dr. Iestyn Woolway of Bangor University said, “We still don’t know exactly how floating panels might affect the ecosystem within a natural lake, in different conditions and locations. But the potential gain in energy generation from FPV is clear, so we need to put that research in place so this technology can be safely adopted. We chose 10% of a lake’s surface area as a likely safe level of deployment, but that might need to be reduced in some situations, or could be higher in others.”
The research shows five nations, including Papua New Guinea, Ethiopia, and Rwanda, could meet their entire electricity needs from FPV. Others, such as Bolivia and Tonga, could meet 87% and 92% of their demand. Many countries, particularly in Africa, the Caribbean, South America, and Central Asia, could meet 40% to 70% of their electricity needs through FPV. In Europe, Finland could meet 17% and Denmark 7% of their demand.
The UK could generate 2.7 TWh annually from FPV, enough to power around one million homes. The UK’s largest FPV installation is a 6.3 MW floating solar farm on the Queen Elizabeth II reservoir near London.
Dr. Woolway added, “Even with the criteria we set to create a realistic scenario for deployment of FPV, there are benefits across the board, mainly in lower income countries with high levels of sunshine, but also in Northern European countries as well. The criteria we chose were based on obvious exclusions, such as lakes in protected areas, but also on what might reduce the cost and risks of deployment.”
Co-author Professor Alona Armstrong of Lancaster University said, “Our work shows there is much potential for FPV around the world. But deployments need to be strategic, considering the consequences for energy security, nature and society, as well as Net Zero.”
The research is funded by the Natural Environment Research Council, part of UK Research and Innovation.
Research Report:Decarbonisation potential of floating solar photovoltaics on lakes worldwide
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