Solar Energy
Decades of Solar Mirror Research Now Accessible in New Database

Decades of Solar Mirror Research Now Accessible in New Database
by Simon Mansfield
Sydney, Australia (SPX) Nov 01, 2023
The National Renewable Energy Laboratory (NREL), part of the U.S. Department of Energy, is set to launch an extensive database cataloging the outcomes of decades-long exposure tests on solar mirrors. Known as the Solar Mirror Materials Database (SMMD), this resource promises to house a vast array of data, encompassing over 2,000 samples and 100,000 measurements from more than 100 suppliers. Designed to serve the solar-thermal power industry, the database aims to become a cornerstone in research and development.
NREL’s exhaustive solar mirror study spans a timeline reaching back to 1980. It offers deep insights into the durability and degradation of various materials that make up the mirrors commonly used in concentrating solar-thermal power systems. These mirrors have been exposed to a variety of testing conditions, in both outdoor settings and lab environments, across three locations: Phoenix, Miami, and NREL’s own campus in Golden, Colorado.
The research has been condensed into an article, “Compilation of a Solar Mirror Materials Database and an Analysis of Natural and Accelerated Mirror Exposure and Degradation,” published in the Journal of Solar Energy Engineering. Authored by Tucker Farrell, a research engineer at NREL, alongside co-authors Yue Cao, Daniel Celvi, Christa Schreiber, and Guangdong Zhu, the paper applies statistical analysis to synthesize decades of measurement data.
Tucker Farrell explained the utility of the SMMD, saying, “The database can guide the development of accelerated tests, design of solar reflectors, and manufacturing processes.” He elaborated on the scope of solar-thermal technology: “You’ve got a variety of forms like parabolic trough, tower, Fresnel, dish, and more, but they all center around a single principle. You aim to reflect and concentrate solar energy at a focal point to capture heat.”
The information within the SMMD is considered exceptionally valuable for its long-term outdoor exposure data. One significant observation made by the NREL team was a strong correlation between four months of accelerated lab testing and nine months of outdoor exposure. This suggests that extended durations in lab conditions are essential for precise modeling of material behavior over time.
The varying climatic conditions at the three test sites provide additional layers of nuance to the research. Phoenix offered the lowest humidity and highest daily temperature ranges, while Miami presented high humidity levels but stable temperatures. Golden experienced the lowest average temperatures but had considerable temperature fluctuations. This range allows for more comprehensive conclusions about how different environmental factors interact with solar mirror materials.
Mirrors used in the studies consisted of various combinations of materials such as glass and aluminum, polymer and silver, or glass and silver. While it’s a given that solar mirrors degrade over time, losing some of their reflectivity, the SMMD aims to offer a deeper understanding of the underlying causes. Factors like corrosion, microfractures, pitting, and other chemical and physical changes have been explored in the database. This enables the development of more targeted and environment-specific solutions. For instance, a mirror designed for arid climates with coarse sand may not be optimal for coastal settings with high humidity and airborne salts.
Funded by the U.S. Department of Energy’s Solar Energy Technologies Office, the research embodied in the SMMD serves as a rich resource for the development and refinement of solar mirror technologies. The SMMD is expected to be accessible online later this year, offering a comprehensive tool for both researchers and industry professionals.
NREL operates as the U.S. Department of Energy’s premier lab for research and development in renewable energy and energy efficiency, managed by the Alliance for Sustainable Energy LLC.
Research Report:Compilation of a Solar Mirror Materials Database and an Analysis of Natural and Accelerated Mirror Exposure and Degradation
Relevance Scores:
1. Renewable Energy Industry Analyst: 9/10
2. Stock and Finance Market Analyst: 7/10
3. Government Policy Analyst: 8/10
Analyst Summary:
The article focuses on the National Renewable Energy Laboratory (NREL)’s upcoming Solar Mirror Materials Database (SMMD), a comprehensive compilation of decades-long research on solar mirrors, particularly their durability and degradation. This initiative is primarily aimed at serving the solar-thermal power industry.
Renewable Energy Industry Analyst:
For renewable energy professionals, especially those in the solar-thermal sector, the database is a treasure trove. It covers critical aspects like material degradation and performance under various climatic conditions. The in-depth data could accelerate R and D efforts and potentially lead to more efficient and durable solar mirrors.
Stock and Finance Market Analyst:
From a financial standpoint, this development has implications for companies involved in manufacturing solar mirrors and those investing in solar-thermal projects. The data could reduce risks associated with long-term investments by offering insights into material longevity and performance. However, the database mainly serves the solar-thermal industry, limiting its broader applicability in the entire renewable energy sector.
Government Policy Analyst:
For policy analysts, the database offers concrete data that could inform future policy decisions on renewable energy, particularly solar-thermal technologies. Given that the research is funded by the U.S. Department of Energy, the government would have a vested interest in utilizing this information to shape grants, incentives, and regulations.
Historical Context:
Over the past 25 years, the renewable energy sector has seen significant advancements in technology, efficiency, and scalability. Early solar thermal projects were fraught with issues of inefficiency and durability, many of which this database aims to address. Additionally, in terms of policy, there has been an increased focus on renewable energies as part of sustainable development goals and climate commitments. The SMMD can be seen as a confluence of these advancements and policy directions, offering empirical data to support future initiatives.
Investigative Questions:
1. How can the data in the SMMD be used to create a more sustainable solar-thermal energy supply chain?
2. What are the financial implications of implementing the database’s findings in existing solar-thermal projects?
3. How will the SMMD influence governmental policies around renewable energy subsidies and tax incentives?
4. Could the methodology of the SMMD be applied to other forms of renewable energy technologies for similar benefits?
5. How might the SMMD impact international collaborations on renewable energy research and development?
The SMMD promises to be a valuable resource across different sectors, impacting R and D, investment strategies, and policy formulation in the realm of renewable energy.
Related Links
National Renewable Energy Laboratory
All About Solar Energy at SolarDaily.com
Solar Energy
Identifying Key Organic-Inorganic Interaction Sites for Enhanced Emission in Hybrid Perovskites via Pressure Engineering

Identifying Key Organic-Inorganic Interaction Sites for Enhanced Emission in Hybrid Perovskites via Pressure Engineering
by Simon Mansfield
Sydney, Australia (SPX) Mar 14, 2025
A research team from Jilin University has developed a new approach using pressure engineering to pinpoint organic-inorganic interaction sites in non-hydrogen-bonded hybrid metal perovskites. This innovative method provides valuable insight into the photophysical mechanisms governing hybrid perovskites and offers guidance for designing materials with tailored optical properties.
“Previous research has primarily focused on the role of hydrogen bonding in shaping the photophysical properties of hybrid perovskites,” explained Guanjun Xiao, the study’s lead researcher. “However, the lack of investigation into the interaction mechanisms of non-hydrogen-bonded hybrid perovskites has hindered precise material design for targeted applications.”
By employing high-pressure techniques, Xiao and his team studied the specific interaction sites within the non-hydrogen-bonded hybrid perovskite (DBU)PbBr3. Their findings highlighted that the spatial arrangement of Br-N atomic pairs plays a crucial role in influencing organic-inorganic interactions.
The research was published on September 16 in *Research*, a Science Partner Journal launched by the American Association for the Advancement of Science (AAAS) in collaboration with the China Association for Science and Technology (CAST). Xiao is a professor at the State Key Laboratory of Superhard Materials at Jilin University.
The study involved synthesizing microrod (DBU)PbBr3 using the hot injection method and systematically analyzing its optical and structural properties under high pressure. The researchers observed that the material’s emission exhibited enhancement and a blue shift under pressure, with photoluminescence quantum yield reaching 86.6% at 5.0 GPa. Additionally, photoluminescence lifetime measurements indicated a suppression of non-radiative recombination under pressure.
A significant discovery was the presence of an abnormally enhanced Raman mode in the pressure range where emission enhancement occurred. “This suggests a potential connection between the two phenomena,” Xiao noted. Further analysis identified the Raman mode as being linked to organic-inorganic interactions, likely associated with N-Br bonding.
To deepen their understanding, the team conducted structural evolution studies under pressure, supported by first-principles calculations. They confirmed that the primary determinants of interaction strength were the spatial arrangement of N and Br atoms, including their distance and dihedral angle. A notable isostructural phase transition at 5.5 GPa altered the primary compression direction, initially strengthening organic-inorganic interactions before leading to a subsequent decrease-trends that aligned with observed optical property changes.
“These findings bridge a significant knowledge gap in understanding organic-inorganic interactions in non-hydrogen-bonded hybrid halides, offering valuable design principles for materials with specific optical performance targets,” Xiao stated.
Research Report:Identifying Organic-Inorganic Interaction Sites Toward Emission Enhancement in Non-Hydrogen-Bonded Hybrid Perovskite via Pressure Engineering
Related Links
State Key Laboratory of Superhard Materials, College of Physics, Jilin University
All About Solar Energy at SolarDaily.com
Solar Energy
Cheap and environmentally friendly – the next generation LEDs may soon be here

Cheap and environmentally friendly – the next generation LEDs may soon be here
by Anders Torneholm
Linkoping, Sweden (SPX) Mar 13, 2025
Cost, technical performance and environmental impact – these are the three most important aspects for a new type of LED technology to have a broad commercial impact on society. This has been demonstrated by researchers at Linkoping University in a study published in Nature Sustainability.
“Perovskite LEDs are cheaper and easier to manufacture than traditional LEDs, and they can also produce vibrant and intense colours if used in screens. I’d say that this is the next generation of LED technology,” says Feng Gao, professor of optoelectronics at Linkoping University.
However, for a technological shift to take place, where today’s LEDs are replaced with those based on the material perovskite, more than just technical performance is required. That is why Feng Gao’s research group has collaborated with Professor Olof Hjelm and John Laurence Esguerra, assistant professor at LiU. They specialise in how innovations contributing to environmental sustainability can be introduced to the market.
Together, they have investigated the environmental impact and cost of 18 different perovskite LEDs, knowledge that is currently incomplete. The study was conducted using so-called life cycle assessment and techno-economic assessment.
Such analyses require a clear system definition – that is, what is included and not in terms of cost and environmental impact. Within this framework, what happens from the product being created until it can no longer be used is investigated. The life cycle of the product, from cradle to grave, can be divided into five different phases: raw material production, manufacturing, distribution, use and decommissioning.
“We’d like to avoid the grave. And things get more complicated when you take recycling into account. But here we show that it’s most important to think about the reuse of organic solvents and how raw materials are produced, especially if they are rare materials,” says Olof Hjelm.
One example where the life cycle analysis provides guidance concerns the small amount of toxic lead found in perovskite LEDs. This is currently necessary for the perovskites to be effective. But, according to Olof Hjelm, focusing only on lead is a mistake. There are also many other materials in LEDs, such as gold.
“Gold production is extremely toxic. There are byproducts such as mercury and cyanide. It’s also very energy-consuming,” he says.
The greatest environmental gain would instead be achieved by replacing gold with copper, aluminium or nickel, while maintaining the small amount of lead needed for the LED to function optimally.
The researchers have concluded that perovskite LEDs have great potential for commercialisation in the long term. Maybe they can even replace today’s LEDs, thanks to lower costs and less environmental impact. The big issue is longevity. However, the development of perovskite LEDs is accelerating and their life expectancy is increasing. The researchers believe that it needs to reach about 10,000 hours for a positive environmental impact, something they think is achievable. Today, the best perovskite LEDs last for hundreds of hours.
Muyi Zhang, PhD student at the Department of Physics, Chemistry and Biology at LiU, says that much of the research focus so far is on increasing the technical performance of LED, something he believes will change.
“We want what we develop to be used in the real world. But then, we as researchers need to broaden our perspective. If a product has high technical performance but is expensive and isn’t environmentally sustainable, it may not be highly competitive in the market. That mindset will increasingly come to guide our research.”
Research Report:Towards sustainable perovskite light-emitting diodes
Related Links
Linkoping University
All About Solar Energy at SolarDaily.com
Solar Energy
Making solar projects cheaper and faster with portable factories

Making solar projects cheaper and faster with portable factories
by Zach Winn | MIT News
Boston MA (SPX) Mar 13, 2025
As the price of solar panels has plummeted in recent decades, installation costs have taken up a greater share of the technology’s overall price tag. The long installation process for solar farms is also emerging as a key bottleneck in the deployment of solar energy.
Now the startup Charge Robotics is developing solar installation factories to speed up the process of building large-scale solar farms. The company’s factories are shipped to the site of utility solar projects, where equipment including tracks, mounting brackets, and panels are fed into the system and automatically assembled. A robotic vehicle autonomously puts the finished product – which amounts to a completed section of solar farm – in its final place.
“We think of this as the Henry Ford moment for solar,” says CEO Banks Hunter ’15, who founded Charge Robotics with fellow MIT alumnus Max Justicz ’17. “We’re going from a very bespoke, hands on, manual installation process to something much more streamlined and set up for mass manufacturing. There are all kinds of benefits that come along with that, including consistency, quality, speed, cost, and safety.”
Last year, solar energy accounted for 81 percent of new electric capacity in the U.S., and Hunter and Justicz see their factories as necessary for continued acceleration in the industry.
The founders say they were met with skepticism when they first unveiled their plans. But in the beginning of last year, they deployed a prototype system that successfully built a solar farm with SOLV Energy, one of the largest solar installers in the U.S. Now, Charge has raised $22 million for its first commercial deployments later this year.
From surgical robots to solar robots
While majoring in mechanical engineering at MIT, Hunter found plenty of excuses to build things. One such excuse was Course 2.009 (Product Engineering Processes), where he and his classmates built a smart watch for communication in remote areas.
After graduation, Hunter worked for the MIT alumni-founded startups Shaper Tools and Vicarious Surgical. Vicarious Surgical is a medical robotics company that has raised more than $450 million to date. Hunter was the second employee and worked there for five years.
“A lot of really hands on, project-based classes at MIT translated directly into my first roles coming out of school and set me up to be very independent and run large engineering projects,” Hunter says, “Course 2.009, in particular, was a big launch point for me. The founders of Vicarious Surgical got in touch with me through the 2.009 network.”
As early as 2017, Hunter and Justicz, who majored in mechanical engineering and computer science, had discussed starting a company together. But they had to decide where to apply their broad engineering and product skillsets.
“Both of us care a lot about climate change. We see climate change as the biggest problem impacting the greatest number of people on the planet,” Hunter says. “Our mentality was if we can build anything, we might as well build something that really matters.”
In the process of cold calling hundreds of people in the energy industry, the founders decided solar was the future of energy production because its price was decreasing so quickly.
“It’s becoming cheaper faster than any other form of energy production in human history,” Hunter says.
When the founders began visiting construction sites for the large, utility-scale solar farms that make up the bulk of energy generation, it wasn’t hard to find the bottlenecks. The first site they traveled to was in the Mojave Desert in California. Hunter describes it as a massive dust bowl where thousands of workers spent months repeating tasks like moving material and assembling the same parts, over and over again.
“The site had something like 2 million panels on it, and every single one was assembled and fastened the same way by hand,” Hunter says. “Max and I thought it was insane. There’s no way that can scale to transform the energy grid in a short window of time.”
Hunter says he heard from each of the largest solar companies in the U.S. that their biggest limitation for scaling was labor shortages. The problem was slowing growth and killing projects.
Hunter and Justicz founded Charge Robotics in 2021 to break through that bottleneck. Their first step was to order utility solar parts and assemble them by hand in their backyards.
“From there, we came up with this portable assembly line that we could ship out to construction sites and then feed in the entire solar system, including the steel tracks, mounting brackets, fasteners, and the solar panels,” Hunter explains. “The assembly line robotically assembles all those pieces to produce completed solar bays, which are chunks of a solar farm.”
Each bay represents a 40-foot piece of the solar farm and weighs about 800 pounds. A robotic vehicle brings it to its final location in the field. Hunter says Charge’s system automates all mechanical installation except for the process of pile driving the first metal stakes into the ground.
Charge’s assembly lines also have machine-vision systems that scan each part to ensure quality, and the systems work with the most common solar parts and panel sizes.
From pilot to product
When the founders started pitching their plans to investors and construction companies, people didn’t believe it was possible.
“The initial feedback was basically, ‘This will never work,'” Hunter says. “But as soon as we took our first system out into the field and people saw it operating, they got much more excited and started believing it was real.”
Since that first deployment, Charge’s team has been making its system faster and easier to operate. The company plans to set up its factories at project sites and run them in partnership with solar construction companies. The factories could even run alongside human workers.
“With our system, people are operating robotic equipment remotely rather than putting in the screws themselves,” Hunter explains. “We can essentially deliver the assembled solar to customers. Their only responsibility is to deliver the materials and parts on big pallets that we feed into our system.”
Hunter says multiple factories could be deployed at the same site and could also operate 24/7 to dramatically speed up projects.
“We are hitting the limits of solar growth because these companies don’t have enough people,” Hunter says. “We can build much bigger sites much faster with the same number of people by just shipping out more of our factories. It’s a fundamentally new way of scaling solar energy.”
Video: “Charge Robotics Sunrise fully autonomous solar construction system”
Related Links
Department of Mechanical Engineering
All About Solar Energy at SolarDaily.com
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