Solar Energy
Smart glass has a bright future

Buildings are responsible for 40 percent of primary energy consumption and 36 percent of total CO2 emissions. And, as we know, CO2 emissions trigger global warming, sea level rise, and profound changes in ocean ecosystems. Substituting the inefficient glazing areas of buildings with energy efficient smart glazing windows has great potential to decrease energy consumption for lighting and temperature control.
Harmut Hillmer et al. of the University of Kassel in Germany demonstrate that potential in “MOEMS micromirror arrays in smart windows for daylight steering,” a paper published recently in the inaugural issue of the Journal of Optical Microsystems.
“Our smart glazing is based on millions of micromirrors, invisible to the bare eye, and reflects incoming sunlight according to user actions, sun positions, daytime, and seasons, providing a personalized light steering inside the building,” Hillmer said.
The micromirror array is invulnerable to wind, window cleaning, or any weather conditions because it is located in the space between the windowpanes filled with noble gas such as argon or krypton. The glazing provides free solar heat in winter and overheating prevention in summer, and it enables healthy natural daylight, huge energy savings (up to 35 percent), massive CO2 reduction (up to 30 percent), and a reduction of 10 percent steel and concrete in high-rise buildings.
Apart from the energy problem, artificial lighting also has consequences for health and well-being. Various studies have linked artificial lighting to lack of concentration, high susceptibility to illness, disturbed biorhythms, and sleeplessness. Smart glass can reduce reliance on artificial lighting by optimizing natural daylight in a room.
Current state-of-the-art smart glazings are currently optimized either for winter or for summer-and not able to ensure energy-saving performance year-round. There has been a need for a smart and automatic technology that can react to local climate (daytime, season), uses available sunlight, regulates light and temperature, and saves substantial energy.
The researchers’ MEMS micromirror arrays are integrated inside insulation glazing and are operated by an electronic control system. The orientation of mirrors is controlled by the voltage between respective electrodes. Motion sensors in the room detect the number, position, and movement of users in the room.
The results include much higher actuation speed in the sub-ms range, 40-times lower power consumption than electrochromic or liquid crystal concepts, reflection instead of absorption, and color neutrality. Rapid aging tests of the micromirror structure were performed to study reliability and revealed sustainability, robustness, and long lifetimes of the micromirror arrays.
And with positive results like that, the benefits of this smart glass are crystal clear.
Solar Energy
Hybrid Transparent Electrodes Boost Efficiency and Lifespan of Perovskite Solar Cells

Hybrid Transparent Electrodes Boost Efficiency and Lifespan of Perovskite Solar Cells
by Simon Mansfield
Sydney, Australia (SPX) Feb 21, 2025
Bifacial perovskite solar cells, known for their ability to capture sunlight from both the front and rear surfaces, have taken a significant step forward thanks to researchers at the Indian Institute of Technology (IIT) Dharwad. Their development of a novel NiO/Ag/NiO (NAN) hybrid transparent electrode has led to enhancements in efficiency, durability, and infrared transparency, opening new possibilities for solar energy applications.
A recent study published in the Journal of Photonics for Energy (JPE) details how the IIT Dharwad team designed and fabricated highly transparent bifacial solar cells utilizing a three-layer NAN electrode. This innovative structure, created using a low-energy physical vapor deposition method, resulted in an electrode with extremely low electrical resistance and high transmittance of visible light.
When incorporated into the bifacial solar cells, the NAN transparent electrode delivered impressive power conversion efficiencies (PCE), achieving 9.05% and 6.54% when exposed to light from different directions. The cells also exhibited a high bifaciality factor of 72%, demonstrating their effectiveness in utilizing light from both sides.
Beyond efficiency, these solar cells displayed exceptional durability, retaining 80% of their initial performance for over 1,000 hours without the need for protective encapsulation. Additionally, their ability to transmit substantial near-infrared light makes them suitable for applications such as thermal windows and advanced optoelectronic technologies.
With a thickness of less than 40 nm, the NAN electrode is particularly advantageous for integration into building materials and tandem solar cell systems. Senior researcher Dhriti Sundar Ghosh, an associate professor of physics at IIT Dharwad, emphasized the broad implications of their work, stating, “This study offers a blueprint for designing transparent electrodes in bifacial perovskite solar cells, paving the way for advancements in tandem devices, agrivoltaics, and automotive solar technologies.”
The findings reinforce the growing potential of bifacial perovskite solar cells in renewable energy solutions, contributing to the development of more efficient and adaptable solar power technologies.
Research Report:Hybrid top transparent electrode for infrared-transparent bifacial perovskite solar cells
Related Links
Indian Institute of Technology
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Solar Energy
Bio-inspired approach creates bespoke photovoltaics

Bio-inspired approach creates bespoke photovoltaics
by David Nutt for Cornell Chronicle
Ithica NY (SPX) Feb 21, 2025
There is more to photovoltaic panels than the materials that comprise them: The design itself can also drive – or potentially diminish – the widespread adoption of solar technology.
Put bluntly: Most solar panels are not much to look at. And their flat, nonflexible composition means they can only be affixed to similarly flat structures. But what if photovoltaic panels were instead a hinged, lightweight fabric that was aesthetically attractive and could wrap around complex shapes, even contorting its form to better absorb sunlight?
Thus was born the idea for HelioSkin, an interdisciplinary project led by Jenny Sabin, the Arthur L. and Isabel B. Weisenberger Professor in Architecture in the College of Architecture, Art and Planning at Cornell University, in collaboration with Itai Cohen, professor of physics in the College of Arts and Sciences, and Adrienne Roeder, professor in the Section of Plant Biology in the School of Integrative Plant Science, in the College of Agriculture and Life Sciences and at the Weill Institute for Cell and Molecular Biology.
“What we’re really passionate about is how the system could not only produce energy in a passive way, but create transformational environments in urban or urban-rural settings,” Sabin said. “Sustainability is about performance and function, but equally, it’s about beauty and getting people to get excited about it, so they want to participate. The grand goal is to inspire widespread adoption of solar for societal impact.”
Sabin, the inaugural chair of the new multicollege Department of Design Tech, has made a career of collaborating with diverse disciplines and taking cues not just from architecture, but also engineering. And physics. And mathematics. And, perhaps most importantly, biology. All of her projects are united by the same question: How might buildings and their integrated material systems behave more like organisms, responding and adapting to their local environments?
“Nature is not efficient,” Sabin said. “It’s resilient, and biology is in it for the long game, over much longer time scales. Additionally, it has been demonstrated that plants that track the sun exhibit a photosynthetic advantage. And we think that’s a pretty powerful way to think about sustainability and resiliency in architecture.”
Sabin’s design interests address a very real need. The primary convergent problem is that 40% of total greenhouse gas emissions in the United States comes from buildings, according to the International Energy Agency.
“By developing a new solar skin product that can scale, we aim to turn the needle by getting homeowners and businesses to adopt solar to reduce the 28% of CO2 that comes from the heating, lighting and cooling of buildings,” Sabin said.
HelioSkin originated in a partnership between Sabin and Mariana Bertoni, an energy engineer at Arizona State University, who is also a member of the HelioSkin team. Together they combined computational design, digital fabrication and 3D printing to create customized filters and photovoltaic panel assemblies – what Sabin calls “nonstandard angularity” – that could simultaneously boost light absorption and architectural beauty. The key to that effort was looking at the mechanics of heliotropism – how sunflowers track sunlight.
For HelioSkin, that research foundation expanded to include Roeder’s expertise in heliotropism and cellular morphogenesis – i.e., how plant cells grow to bend the plant toward the sun – and Cohen’s specialization in using geometric methods such as origami and kirigami to improve the mechanical performance of metamaterials, increasing their flexibility while expending very little energy.
The flowering Arabidopsis plant is an ideal model for HelioSkin because, as “the fruit fly of the plant world” according to Roeder, it’s easy to study at the cellular level. Those cells play a vital role in changing the curvature of the plant’s stem as it angles toward the sunlight, with the Arabidopsis’ hormones causing the cells on its sunless side to expand by 25%, bending the stem 90 degrees.
“We’ve already figured out how to translate our plant cells’ tracking mechanism into Jenny’s architectural software,” Roeder said. “Now we have to start figuring out how to make that transition in HelioSkin.”
‘The human-centered design process’
The ultimate goal is to generate a mechanically tracking solar-collection skin for retractable roofs, stadiums and skyscrapers, but to get there, the team is launching a three-year pilot project whereby they create small solar canopies for backyards, which can then be scaled up for urban parks.
Bringing that vision to market not only involves scientific innovation and smart design, but requires industry partnerships, capital and a marketing plan.
The project was launched through the National Science Foundation’s Convergence Accelerator program, which last year awarded the team $650,000 in phase I funding. The team has applied for the next phase of funding – $5 million over three years.
The industry partners include E Ink and Rainier Industries, which are helping integrate photovoltaics and ePaper onto lightweight, stretchable architectural fabric. SunFlex, a company that uses laser-welded back contact module technology for photovoltaics manufacturing, is onboard to help refine the HelioSkin prototypes in phase 2 – the sensing, the wiring, the arrangement of the panels, plus the geometry and substrate.
By the pilot project’s second year, the team plans to have a full-scale backyard canopy prototype that can potentially provide light and power outdoor appliances; by the third year, they aim to be in the early stages of commercialization.
As part of their commercialization plan, the team conducted extensive marketing analysis and interviews that showed HelioSkin’s gross cost, the cost-per-watt and system capacity were competitive with existing PV products.
“This was a really encouraging and exciting process to go through, to see how we compare to existing products and the potential that we have to then scale,” Sabin said. “The human-centered design process, including engaging people in many different industries, from end users to potential stakeholders to people that work for the energy grid and the state or the region – that’s been a big part of our process, and it’s been really helpful.”
The analysis revealed niche applications that the team hadn’t initially considered, such as “big box” commercial businesses that want to pursue solar to attain net-zero emissions but are also interested in display advertising or colorful pattern change for aesthetic applications. To that end, the team is working with E Ink to create a HelioSkin with electrically powered responsive display features, so solar skins can be placed on retail structures and stadiums and function as ever-changing billboards.
“This was something that came out of interviews,” Sabin said. “We had never thought about these types of applications.”
One of the virtues of working with E Ink is the company uses roll-to-roll printing to mass produce photovoltaic sheets – the same method that makes the low-cost manufacturing of perovskite photovoltaics feasible.
“The basic idea is to try to print things in 2D, which is cheap, and then morph it into 3D, allowing it to curve around structures,” Cohen said. “You can’t just take a normal sheet of paper and wrap something. It’s going to have all sorts of creases to it. Like if you try to wrap an orange, you get all these crinkles. One of the innovations that we came up with was to cut the paper into a pattern of panels and hinges that allows it to locally stretch around these round objects. A second strategy we came up with is to use fabric as a way to make the hinge. Fabric is floppy enough to give you that hinge-like behavior.”
In her experimental architecture practice, Sabin has spent more than 15 years developing large urban-scale canopies and architectural installations, experience that has served her well in launching a product.
“There’s a strong focus on commercialization and developing IP management plans. As a designer, I have a practice, and so I find this really interesting,” Sabin said. “But it’s also completely new for most of my collaborators. They don’t necessarily think about this level of application and spinning out a product. So the learning curve around that is pretty steep for all of us.”
The ability to collaborate across disciplines is what initially drew Sabin to Cornell in 2011. It’s a place where “everybody has their door open,” she said. The excitement, and the opportunities for impact, are palpable.
“Bottom line, we are in New York’s mecca for solar,” she said. “So there’s a lot going on, both in terms of innovative research, but also applied systems, in farming and agrivoltaics, solar farms, etc. So that dynamic community of people actively working on a common set of goals and questions and problems is super exciting for us, too.”
Related Links
Department of Design Tech at Cornell
All About Solar Energy at SolarDaily.com
Solar Energy
China aims to add 200 GW in renewables

China aims to add 200 GW in renewables
by Simon Mansfield
Sydney, Australia (SPX) Mar 04, 2025
China is poised to make another substantial push in renewable energy expansion this year, targeting the addition of more than 200 gigawatts of renewable capacity. According to the National Energy Administration (NEA), this will contribute to an overall power generation capacity of approximately 10.6 trillion kilowatt-hours in 2025.
The nation’s total installed power capacity is expected to exceed 3.6 billion kilowatts by the end of the year, as outlined in the NEA’s newly released energy work guidelines. China is also advancing efforts to establish a unified national power market, with non-fossil fuel power generation projected to make up around 60 percent of total installed capacity. Additionally, non-fossil energy is anticipated to constitute about 20 percent of total energy consumption.
Industry analysts indicate that while new market-based pricing mechanisms for renewable energy grid connections introduce some uncertainty, the 200 GW target, though moderate, still provides ample opportunities for stakeholders in the renewable energy sector.
“The 200 GW installation goal for this year accounts for just 56 percent of the total wind and solar capacity added in 2024, but it underscores China’s continued commitment to renewable energy,” noted Zhu Yicong, vice-president of renewables and power research at Rystad Energy.
Zhu also acknowledged concerns raised following the NEA’s latest directive requiring renewable energy producers to fully integrate into power markets and adhere to market-based electricity pricing from June. “Although a vast number of renewable projects are either under development or nearing construction across various provinces, uncertainties regarding future financial returns could lead to delays in project implementation,” she said.
To enhance the market value of renewable energy and align prices with supply-demand dynamics, the National Development and Reform Commission and the NEA recently issued a notice emphasizing competitive market mechanisms for electricity pricing.
Industry projections suggest that renewable electricity prices could decline under the new pricing system, given the low variable costs associated with sources such as solar power, particularly during peak daylight hours. This price decline could introduce hesitation among investors assessing new projects.
Despite a relatively modest target for new installations this year, the industry sees this as a strategic approach, allowing developers time to adapt to evolving market conditions. “The moderate goal enables market participants to refine sustainable strategies without facing excessive pressure for rapid installation,” Zhu added.
Experts recommend that renewable energy developers navigate the transition to market-driven pricing by securing power purchase agreements, integrating battery storage solutions, and optimizing energy output for competitiveness.
China continues to prioritize renewable energy as a fundamental component of its green economy and dual-carbon objectives. In 2024, newly installed renewable capacity accounted for 86 percent of the nation’s total new power installations. The cumulative share of renewables in the country’s total installed capacity reached a record 56 percent, according to NEA data.
While renewable energy development surges, China’s overall energy production is set to maintain steady growth. Coal production will remain stable with some planned expansion, while crude oil output is expected to stay above 200 million metric tons. The country also plans to bolster its oil and gas reserves to enhance energy security.
Related Links
National Energy Administration
All About Solar Energy at SolarDaily.com
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