Solar Energy
Seizing solar’s bright future
Seizing solar’s bright future
by Leda Zimmerman | MIT Energy Initiative
Boston MA (SPX) May 07, 2024
Consider the dizzying ascent of solar energy in the United States: In the past decade, solar capacity increased nearly 900 percent, with electricity production eight times greater in 2023 than in 2014. The jump from 2022 to 2023 alone was 51 percent, with a record 32 gigawatts (GW) of solar installations coming online. In the past four years, more solar has been added to the grid than any other form of generation. Installed solar now tops 179 GW, enough to power nearly 33 million homes. The U.S. Department of Energy (DOE) is so bullish on the sun that its decarbonization plans envision solar satisfying 45 percent of the nation’s electricity demands by 2050.
But the continued rapid expansion of solar requires advances in technology, notably to improve the efficiency and durability of solar photovoltaic (PV) materials and manufacturing. That’s where Optigon, a three-year-old MIT spinout company, comes in.
“Our goal is to build tools for research and industry that can accelerate the energy transition,” says Dane deQuilettes, the company’s co-founder and chief science officer. “The technology we have developed for solar will enable measurements and analysis of materials as they are being made both in lab and on the manufacturing line, dramatically speeding up the optimization of PV.”
With roots in MIT’s vibrant solar research community, Optigon is poised for a 2024 rollout of technology it believes will drastically pick up the pace of solar power and other clean energy projects.
Beyond silicon
Silicon, the material mainstay of most PV, is limited by the laws of physics in the efficiencies it can achieve converting photons from the sun into electrical energy. Silicon-based solar cells can theoretically reach power conversion levels of just 30 percent, and real-world efficiency levels hover in the low 20s. But beyond the physical limitations of silicon, there is another issue at play for many researchers and the solar industry in the United States and elsewhere: China dominates the silicon PV market, from supply chains to manufacturing.
Scientists are eagerly pursuing alternative materials, either for enhancing silicon’s solar conversion capacity or for replacing silicon altogether.
In the past decade, a family of crystal-structured semiconductors known as perovskites has risen to the fore as a next-generation PV material candidate. Perovskite devices lend themselves to a novel manufacturing process using printing technology that could circumvent the supply chain juggernaut China has built for silicon. Perovskite solar cells can be stacked on each other or layered atop silicon PV, to achieve higher conversion efficiencies. Because perovskite technology is flexible and lightweight, modules can be used on roofs and other structures that cannot support heavier silicon PV, lowering costs and enabling a wider range of building-integrated solar devices.
But these new materials require testing, both during R and D and then on assembly lines, where missing or defective optical, electrical, or dimensional properties in the nano-sized crystal structures can negatively impact the end product.
“The actual measurement and data analysis processes have been really, really slow, because you have to use a bunch of separate tools that are all very manual,” says Optigon co-founder and chief executive officer Anthony Troupe ’21. “We wanted to come up with tools for automating detection of a material’s properties, for determining whether it could make a good or bad solar cell, and then for optimizing it.”
“Our approach packed several non-contact, optical measurements using different types of light sources and detectors into a single system, which together provide a holistic, cross-sectional view of the material,” says Brandon Motes ’21, ME ’22, co-founder and chief technical officer.
“This breakthrough in achieving millisecond timescales for data collection and analysis means we can take research-quality tools and actually put them on a full production system, getting extremely detailed information about products being built at massive, gigawatt scale in real-time,” says Troupe.
This streamlined system takes measurements “in the snap of the fingers, unlike the traditional tools,” says Joseph Berry, director of the US Manufacturing of Advanced Perovskites Consortium and a senior research scientist at the National Renewable Energy Laboratory. “Optigon’s techniques are high precision and allow high throughput, which means they can be used in a lot of contexts where you want rapid feedback and the ability to develop materials very, very quickly.”
According to Berry, Optigon’s technology may give the solar industry not just better materials, but the ability to pump out high-quality PV products at a brisker clip than is currently possible. “If Optigon is successful in deploying their technology, then we can more rapidly develop the materials that we need, manufacturing with the requisite precision again and again,” he says. “This could lead to the next generation of PV modules at a much, much lower cost.”
Measuring makes the difference
With Small Business Innovation Research funding from DOE to commercialize its products and a grant from the Massachusetts Clean Energy Center, Optigon has settled into a space at the climate technology incubator Greentown Labs in Somerville, Massachusetts. Here, the team is preparing for this spring’s launch of its first commercial product, whose genesis lies in MIT’s GridEdge Solar Research Program.
Led by Vladimir Bulovic, a professor of electrical engineering and the director of MIT.nano, the GridEdge program was established with funding from the Tata Trusts to develop lightweight, flexible, and inexpensive solar cells for distribution to rural communities around the globe. When deQuilettes joined the group in 2017 as a postdoc, he was tasked with directing the program and building the infrastructure to study and make perovskite solar modules.
“We were trying to understand once we made the material whether or not it was good,” he recalls. “There were no good commercial metrology [the science of measurements] tools for materials beyond silicon, so we started to build our own.” Recognizing the group’s need for greater expertise on the problem, especially in the areas of electrical, software, and mechanical engineering, deQuilettes put a call out for undergraduate researchers to help build metrology tools for new solar materials.
“Forty people inquired, but when I met Brandon and Anthony, something clicked; it was clear we had a complementary skill set,” says deQuilettes. “We started working together, with Anthony coming up with beautiful designs to integrate multiple measurements, and Brandon creating boards to control all of the hardware, including different types of lasers. We started filing multiple patents and that was when we saw it all coming together.”
“We knew from the start that metrology could vastly improve not just materials, but production yields,” says Troupe. Adds deQuilettes, “Our goal was getting to the highest performance orders of magnitude faster than it would ordinarily take, so we developed tools that would not just be useful for research labs but for manufacturing lines to give live feedback on quality.”
The device Optigon designed for industry is the size of a football, “with sensor packages crammed into a tiny form factor, taking measurements as material flows directly underneath,” says Motes. “We have also thought carefully about ways to make interaction with this tool as seamless and, dare I say, as enjoyable as possible, streaming data to both a dashboard an operator can watch and to a custom database.”
Photovoltaics is just the start
The company may have already found its market niche. “A research group paid us to use our in-house prototype because they have such a burning need to get these sorts of measurements,” says Troupe, and according to Motes, “Potential customers ask us if they can buy the system now.” deQuilettes says, “Our hope is that we become the de facto company for doing any sort of characterization metrology in the United States and beyond.”
Challenges lie ahead for Optigon: product launches, full-scale manufacturing, technical assistance, and sales. Greentown Labs offers support, as does MIT’s own rich community of solar researchers and entrepreneurs. But the founders are already thinking about next phases.
“We are not limiting ourselves to the photovoltaics area,” says deQuilettes. “We’re planning on working in other clean energy materials such as batteries and fuel cells.”
That’s because the team wants to make the maximum impact on the climate challenge. “We’ve thought a lot about the potential our tools will have on reducing carbon emissions, and we’ve done a really in-depth analysis looking at how our system can increase production yields of solar panels and other energy technologies, reducing materials and energy wasted in conventional optimization,” deQuilettes says. “If we look across all these sectors, we can expect to offset about 1,000 million metric tons of CO2 [carbon dioxide] per year in the not-too-distant future.”
The team has written scale into its business plan. “We want to be the key enabler for bringing these new energy technologies to market,” says Motes. “We envision being deployed on every manufacturing line making these types of materials. It’s our goal to walk around and know that if we see a solar panel deployed, there’s a pretty high likelihood that it will be one we measured at some point.”
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Solar Energy
Argonne to lead National Energy Storage Research Hub
Argonne to lead National Energy Storage Research Hub
by Clarence Oxford
Los Angeles CA (SPX) Sep 05, 2024
The U.S. Department of Energy (DOE) has selected Argonne National Laboratory to lead the newly established Energy Storage Research Alliance (ESRA), a national hub focused on advancing energy storage technologies. The ESRA, co-led by DOE’s Lawrence Berkeley National Laboratory (Berkeley Lab) and Pacific Northwest National Laboratory (PNNL), is one of two new Energy Innovation Hubs announced by the DOE.
Bringing together nearly 50 leading researchers from three national laboratories and 12 universities, ESRA aims to address the most critical challenges in battery technology, such as safety, high-energy density, and the development of long-duration storage solutions using cost-effective and abundant materials. The initiative is designed to push the boundaries of energy storage science, fostering innovation and strengthening the competitive edge of the U.S. in this crucial field.
“The demand for high-performance, low-cost and sustainable energy storage devices is on the rise, especially those with potential to deeply decarbonize heavy-duty transportation and the electric grid,” stated Shirley Meng, ESRA director and chief scientist at the Argonne Collaborative Center for Energy Storage Science. “To achieve this, energy storage technology must reach levels of unprecedented performance, surpassing the capabilities of current lithium-ion technology. The key to making these transformative leaps lies in a robust research and development initiative firmly grounded in basic science.”
Leveraging decades of investment in fundamental science, ESRA will focus on transformative discoveries in materials chemistry, a deeper understanding of electrochemical processes at the atomic level, and establishing the scientific foundations necessary for major advancements in energy storage technology.
“ESRA creates an energy storage research ecosystem with the mission to rapidly innovate, shorten the time between basic discovery and technology development, and train the next-generation workforce,” commented Bryan McCloskey, ESRA deputy director for scientific thrusts and a faculty engineer at Berkeley Lab.
The success of ESRA’s efforts will lead to the development of high-energy batteries that are fire-resistant, capable of providing long-duration storage for multiple days, have a lifespan of several decades, and are constructed from low-cost, widely available materials.
“ESRA will pave the way for innovative energy storage solutions that drive both U.S. prosperity and security,” said Argonne Director Paul Kearns. “As the lead laboratory for ESRA under the Department of Energy’s Office of Science, Argonne takes pride in spearheading this collaborative effort that unites world-leading experts and taps the impressive scientific resources available in national labs and academia.”
The DOE has committed up to $62.5 million in funding for ESRA over the next five years.
In addition to its research goals, the Argonne-led hub will prioritize training a diverse, next-generation battery workforce to meet future manufacturing demands. This will be achieved through innovative training programs that involve industry, academia, and government partnerships.
“Cultivating a diverse workforce dedicated to safeguarding America’s energy resilience is key to ESRA’s mission,” noted Wei Wang, ESRA deputy director for crosscuts and director of the Energy Storage Materials Initiative at PNNL. “Through our strategic equity and inclusion initiatives, we plan to create a robust training ground for energy storage science from the undergraduate to postdoctoral levels.”
With Berkeley Lab and PNNL as co-leads, the ESRA collaboration brings together comprehensive expertise across the energy storage spectrum. Their state-of-the-art capabilities in technology discovery, modeling and simulation, and materials synthesis and characterization complement those of Argonne, setting the stage for significant advancements in energy storage.
Argonne is joined by 14 partners in this initiative, all of whom are deeply involved in ESRA’s scientific endeavors, governance, strategic development, and the training of the next generation of battery scientists and engineers. This collaboration among national laboratories and universities is vital for discovering new materials, accelerating the development of technology, and commercializing new energy storage innovations.
Related Links
Argonne Collaborative Center for Energy Storage Science
Powering The World in the 21st Century at Energy-Daily.com
Solar Energy
UN’s Guterres says China-Africa ties can drive ‘renewable energy revolution’
UN’s Guterres says China-Africa ties can drive ‘renewable energy revolution’
by AFP Staff Writers
Beijing (AFP) Sept 5, 2024
United Nations Secretary-General Antonio Guterres told African leaders Thursday that expanding ties between China and the continent could “drive the renewable energy revolution”.
Guterres and more than 50 African leaders are attending this week’s China-Africa forum, according to state media.
Guterres told the gathering that “China’s remarkable record of development — including on eradicating poverty — provides a wealth of experience and expertise”.
“It can be a catalyst for key transitions on food systems and digital connectivity,” he said.
“And as home to some of the world’s most dynamic economies, Africa can maximise the potential of China’s support in areas from trade to data management, finance and technology,” Guterres added.
Guterres also told the leaders it was time to correct “historic injustices” against the continent.
“It is outrageous… that the continent of Africa has no permanent seat on the Security Council,” he said.
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Solar Energy
Major Qatari plant to double solar capacity by 2030: minister
Major Qatari plant to double solar capacity by 2030: minister
by AFP Staff Writers
Doha (AFP) Sept 1, 2024
A large new solar plant planned in Qatar will double the Gulf emirate’s previously projected renewable energy capacity by 2030, Qatari Energy Minister Saad al-Kaabi announced on Sunday.
The photovoltaic farm, which will be built in the Dukhan area some 80 kilometres (50 miles) west of the capital Doha, will increase the gas-rich state’s solar production capacity to four gigawatts by the end of the decade, Kaabi said.
The plant “that will be established in Dukhan area will produce 2,000 megawatts, which is twice more than the capacity of Qatar’s production of solar energy of the current projects,” the minister, who is also chief executive of state-owned QatarEnergy, said.
In October 2022, Qatar inaugurated its first large-scale solar farm at al-Kharsaah, west of Doha. The emirate announced in August of the same year another solar project with two plants at Ras Laffan in the north.
Through the combined projects, including at Dukhan, Qatar would achieve “4,000 megawatts of clean energy by 2030”, Kaabi said.
This will “constitute 30 percent of the total production of energy of the state of Qatar” with a yearly reduction of “4.7 million tonnes of CO2 emissions,” he added.
Kaabi said the existing projects should produce 1.7 gigawatts of energy “in first quarter of next year, or early next year”.
The energy minister also announced plans to more than double Qatar’s urea production making the country the largest producer of the fertiliser in the world by the end of the decade.
He said Qatar would “maximise the production of chemical fertilisers” through “a complex with global standards” which would “increase our production capacity from 6 million tonnes annually to more than 12.4 million tonnes annually”.
Qatar is one of the world’s top liquefied natural gas producers alongside the United States, Australia and Russia. Natural gas is a major ingredient in urea manufacturing.
In February, Qatar announced plans to expand its output from its North Field project, saying it will boost capacity to 142 million tonnes per year before 2030.
Over the past year, Qatar has inked a series of long-term LNG deals with France’s Total, Britain’s Shell, India’s Petronet, China’s Sinopec and Italy’s Eni among others.
csp/dcp
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