Curved Perovskite Photovoltaic Glass Advances Solar Integration in Electric Vehicles  SolarQuarter
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Standard Solar, a US-based developer, owner and operator of commercial and community PV assets, has acquired a six-project portfolio totaling 28.8 MW from AC Power across New Jersey and Illinois. The community PV portfolio includes projects located on closed landfills and brownfield parcels, converting previously disturbed sites into operational energy installations. Two New Jersey projects totaling about 6 MW are located in Berlin and Freehold and are scheduled for completion in 2027. These New Jersey installations are estimated to generate approximately 7,693 MWh of electricity during their first year of operation. In Illinois, Standard Solar has acquired four projects totaling about 22.8 MW located in South Barrington, Hillsboro and two sites in Lockport. These Illinois installations are expected to generate approximately 33,092 MWh in their first year, with three projects scheduled for completion in 2026. The projects have been developed by AC Power using ballasted racking systems designed to protect landfill caps and maintain existing environmental control systems.

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Korea’s Green Energy Expo to Open April 22 in Daegu, Spotlighting Solar, Storage and Hydroge|Press Release  Solarbe Global
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North Carolina has attracted significant private investment in clean energy in recent years — from battery and solar manufacturing to energy‑efficiency contractor work and grid upgrades.
A new report from the Chambers for Innovation and Clean Energy finds the state’s clean energy job market has grown 13.8% since the pandemic. The group’s executive director, Ryan Evans, said that while solar energy generation initially pushed North Carolina into the nation’s top 10 for clean energy jobs, it’s now clean‑tech manufacturing that’s keeping it there.
Ryan Evans, the group’s executive director, said the state’s ability to supply large industrial users with the electricity they need has become a major selling point.
“We’re seeing a demand for companies to say, ‘OK, who can get me the power that I need for this particular manufacturing center that we want to develop?’” Evans said.
According to the report, manufacturing is now on track to replace renewable energy generation as the state’s second‑largest clean energy employer, behind the energy‑efficiency sector.

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Solar Ireland told the Irish government that the Private Wires Bill’s proposed definition of private wires could bring rooftop solar installations within a full electricity licensing requirement, which would place significant additional demand on the energy regulator and slow down installations.
Solar Ireland CEO Ronan Power in the Irish parliament
Image: Solar Ireland
Solar Ireland CEO Ronan Power addressed the Joint Committee on Climate, Environment and Energy in the Irish parliament this week. He warned that Ireland’s fast-moving residential rooftop solar deployment could be unintentionally slowed under the current wording of the Private Wires Bill. The Private Wires Bill was approved by the government in December 2025 to modernize the country’s electricity system.
It will amend the Electricity Regulation Act 1999 to allow private electricity wires to be built under limited circumstances. The bill sets out four scenarios in consultation with Ireland’s utilities regulator and grid operators. Private wires may be used to facilitate hybrid grid connections, or to link a single user of electricity to a separate singular generation asset. This connection can also include storage technologies.
While Solar Ireland welcomed the potential for the policy to unlock new renewable energy projects, Power warned the Joint Committee that the wording of the bill could skew its implementation – with potentially unfortunate results for Irish residential solar.
Ireland installed 1 GW of solar in 2025, and its development pipeline is around 1.7 GW. Rooftop generation accounts for around half of Ireland’s installed capacity of 2.3 GW.
The problem lies with the proposed definition of private wires which could bring rooftop installations within a full licensing requirement, according to Power.
“Under the definition of private wires as currently drafted, rooftop projects would place significant additional demand on the regulator and risks delaying thousands of households seeking to install solar each year,” the Solar Ireland CEO said, adding that a new regulatory framework should rely on existing technical and safety standards already in use across the solar sector.
Power also said that while private wires can ease constraints on the electricity grid, the potential for distributed solar generation to contribute to Ireland’s energy security should not be overlooked. He said private wires should be a complementary solution rather than a replacement for the national grid.
“Rooftop solar now represents a central component of Ireland’s delivery toward its 2030 renewable energy targets,” Power said, highlighting the rooftop rollout.
The government-run Sustainable Energy Authority of Ireland (SEAI) processed its 100,000th paid application for the Domestic Solar PV Scheme at the end of 2025. Uptake of rooftop solar by homeowners is very high, and supportive grants for domestic installations are being retained into 2026.
“If implemented in a balanced and technically grounded way, this reform can unlock additional renewable capacity, support industrial decarbonization and relieve pressure on the national grid,” said Power.
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A CENTRE that serves all ages in the community is celebrating going greener by generating its own power.
The Carrick Centre in Maybole celebrated another step towards its goal of sustainability by investing in solar panels.
The building, which hosts groups from Baby Steps to seniors’ lunches, is on a journey to become carbon neutral.
It started over a decade ago with a biomass boiler which heats the building, and the centre now boasts energy-efficient lighting, fridges and freezers, and the first accredited Community Green Transport Hub in the UK.
Now the centre has just installed 89 photovoltaic solar panels on the roof together with 40kw of battery storage.
The panels are funded by the Scottish Government’s Community and Renewable Energy Scheme (CARES), with a grant of £53,107.
That was topped up by Net Zero funding of £13,277 from Scottish and Southern Electricity Networks.
Paula Lennox, who pioneered the grant and Tanina Baronello, Carrick Centre community development manager showing off the panels (Image: Contributed)
The fund is administered by the  North Carrick Community Benefit Company until 2028 for non-profit organisations to invest in low-carbon technologies.
Chair Marguerite Hunter Blair said: “By generating our own electricity and heat we are investing in the future of our community through improved social and environmental performance and delivering real cost savings.”
The solar plan has been welcomed by the centre’s board of trustees, two of whom are leading Church of Scotland ministers, Rev Paul Russell and Rev Karlien Becker.
Rev Russell praised the centre, which also houses a church, adding: “Going green is in line with the Church of Scotland’s policy on energy for all congregations to secure a sustainable future.
“A big thank you to Tanina Baronella, Paula Lennox and our generous funders for making this possible.” 
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Today’s Date: March 6, 2026
In the volatile world of renewable energy, few names command the same level of institutional respect and strategic intrigue as First Solar (NASDAQ: FSLR). Long regarded as a “policy play” due to its heavy reliance on domestic manufacturing incentives, the company underwent a radical re-rating in mid-2024 that forever changed its market narrative. On May 22, 2024, the stock experienced a historic 19% single-day surge, a move that signaled First Solar’s emergence not just as a green energy provider, but as a critical infrastructure backbone for the Artificial Intelligence (AI) revolution. As we stand in early 2026, First Solar remains the largest solar manufacturer in the Western Hemisphere, leveraging a unique technological moat and a sold-out order book to navigate a complex macroeconomic and geopolitical landscape.
First Solar’s journey began not in a Silicon Valley garage, but in the glass-manufacturing hub of Toledo, Ohio. Founded in 1990 by physicist Harold McMaster as Solar Cells, Inc., the company’s foundational bet was on Cadmium Telluride (CdTe) thin-film technology. McMaster, a pioneer in tempered glass, believed that solar panels could be manufactured using a continuous, high-speed process similar to flat glass production, rather than the batch-processing required for traditional crystalline silicon.
The company took a decisive turn in 1999 when it was acquired by True North Partners, an investment firm led by the Walton family of Walmart (NYSE: WMT). Rebranded as First Solar, the firm went public in 2006 (NASDAQ: FSLR). Over the next two decades, First Solar survived the “Solar Winter” of the early 2010s—a period that saw dozens of U.S. solar firms go bankrupt due to a flood of cheap, subsidized silicon panels from China. First Solar survived by pivoting away from the residential rooftop market to focus exclusively on utility-scale projects and by relentlessly refining its proprietary CdTe technology.
First Solar’s business model is characterized by deep vertical integration and a niche focus on utility-scale solar. Unlike most competitors who assemble modules from third-party cells and polysilicon, First Solar controls its entire production process—from raw materials to finished panels—under one roof, typically in less than four hours.
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By exiting the Engineering, Procurement, and Construction (EPC) business in 2019, the company streamlined its operations to become a pure-play manufacturer, resulting in higher margins and a cleaner balance sheet.
First Solar has been a storied performer, though its path has been anything but linear.
For the fiscal year 2025, First Solar solidified its position as a cash-flow machine.
CEO Mark Widmar, who took the helm in 2016, is widely credited with First Solar’s modern success. His strategy of “fortifying the moat” involved making the difficult decision to scrap the Series 4 production lines in favor of the larger Series 6 format, a move that initially hurt earnings but ultimately saved the company.
Under Widmar’s leadership, the management team has focused on transparency and “under-promising and over-delivering.” The board of directors maintains a strong emphasis on governance, particularly in light of the Walton family’s significant historical ownership, ensuring that the company’s long-term capital allocation remains disciplined.
First Solar’s primary product is the Series 7 module, designed specifically for the U.S. market.
The solar industry is a battlefield between First Solar’s thin-film and the global dominance of crystalline silicon.
The most significant trend of the last two years has been the AI-Solar Nexus. As tech giants like Alphabet (NASDAQ: GOOGL) and Microsoft (NASDAQ: MSFT) build out massive AI data centers, their power requirements have skyrocketed. Because these “hyperscalers” have 24/7 carbon-neutral goals, they are contracting for solar power at an unprecedented scale.
Furthermore, “Domestic Content” has become the industry’s buzzword. Federal incentives now reward developers for using components made in America, a trend that has funneled almost all high-margin demand directly to First Solar’s doorstep.
Despite its strengths, First Solar is not without significant risks:
Current investor sentiment is “cautiously bullish.” The 19% surge in May 2024, triggered by optimistic notes from UBS and Piper Sandler, set a high bar. As of early 2026, the consensus rating is a Moderate Buy, with a median price target of $256.
While hedge funds have largely maintained their positions, retail sentiment has cooled slightly from the 2024 peaks as investors grapple with the reality of grid delays. However, institutional ownership remains high, as FSLR is seen as a necessary “anchor tenant” in any ESG or infrastructure-themed portfolio.
First Solar sits at the heart of the U.S.-China trade war.
First Solar has evolved from a niche solar manufacturer into a strategic national asset. The May 2024 surge was more than a fluke; it was the market’s realization that the transition to an AI-driven economy requires a massive, reliable, and domestic energy supply chain.
For investors, First Solar offers a unique profile: a high-margin manufacturer with a multi-year backlog and a fortified technological moat. However, the heavy reliance on government subsidies (IRA) and the looming threat of grid interconnection delays require a disciplined approach. As we move further into 2026, the key for First Solar will be its ability to convert its massive backlog into operational reality while maintaining its technological lead through the next generation of Perovskite innovation.
This content is intended for informational purposes only and is not financial advice.

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Senegal is taking a significant step toward strengthening its renewable energy capacity with the launch of a major tender for two large-scale solar power plants. The initiative is being led by the national electricity utility, Senelec, and is aimed at adding 500 MW of photovoltaic (PV) capacity to the country’s power generation portfolio. The project reflects the government’s broader strategy to accelerate the adoption of clean energy and position the country as a key player in West Africa’s renewable energy transition.
The solar development will follow an Engineering, Procurement, and Finance (EPCF) model. Under this framework, selected bidders will be responsible not only for designing and constructing the facilities but also for arranging the financing required for the projects. This approach is intended to attract experienced international developers and investors capable of delivering large-scale renewable infrastructure efficiently.
The tender includes two separate solar power projects located in different regions of the country. The first facility will be built in Linguère with a planned capacity of 200 MW, while the second and larger project will be developed in Kolda with a capacity of 300 MW. Together, these plants will contribute significantly to Senegal’s efforts to expand clean electricity generation and reduce reliance on conventional power sources.
A key feature of the planned solar installations is the integration of large battery energy storage systems. The projects will include battery storage with a capacity of 100 MW and an energy storage capability of 400 MWh. The addition of these systems will help improve grid reliability by addressing the intermittent nature of solar power generation. During periods of high solar production, excess electricity can be stored in the batteries and later released during peak demand or when solar output drops. This capability will enhance grid stability and reduce the likelihood of power disruptions.
The government has also established a relatively strict development schedule. Once contracts are awarded, the selected developers will be required to complete construction within a 24-month period. Interested companies must meet several eligibility criteria, including demonstrating strong financial performance and proven experience in executing large-scale solar energy projects. The deadline for submitting proposals for the tender has been set for April 22, 2026.
This initiative forms part of Senegal’s broader national energy strategy, known as the National Energy Pact, which aims to achieve universal electricity access across the country by 2029. The government has also set an ambitious target to generate 40 percent of its electricity from renewable sources by 2030.
The new solar plants are expected to play an important role in reducing Senegal’s dependence on expensive fossil fuels while also lowering greenhouse gas emissions. The initiative builds on earlier developments in the country’s energy sector, including the Walo Storage project, which introduced lithium-ion battery technology for grid management. With the launch of this 500 MW solar tender, Senegal is further reinforcing its commitment to building a sustainable, resilient, and independent energy system while attracting international investment into its growing renewable energy sector.
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In 2025, North China’s Inner Mongolia autonomous region achieved a major milestone as its installed wind power capacity surpassed 100 million kilowatts, the first in the country to do so.
Throughout the year, the region added 35 million kW of new energy capacity, bringing its total installed capacity of renewables to more than 170 million kW and generating 270 billion kilowatt-hours of electricity.
Inner Mongolia has ranked first nationwide in power generation for more than a decade, with one out of every three kilowatt-hours produced in the region now coming from renewable energy.
Backed by its expanding green power capacity, Inner Mongolia is exploring deeper integration of renewable energy with emerging industries such as computing power, crystalline silicon, and advanced alloy materials, significantly increasing the “green content” of its industrial development.
In Tongliao, green electricity substitution has helped create both a “green power hub” and a “low electricity cost basin”, fostering industrial clusters in green aluminum, wind power equipment manufacturing, and aluminum–nickel–silicon new materials.
In Horinger New Area, the core hub of Hohhot’s computing power industry, dozens of large data centers have been established, with green electricity accounting for as much as 86 percent of their power use, giving the area the top green computing index nationwide.
In Ulaanqab, the rapid transition from traditional energy to renewables in existing ferroalloy capacity has transformed the sector from high-carbon to green production, making the city a national benchmark for green ferroalloy manufacturing.
Meanwhile, Baotou continues to strengthen its status as the “world’s green silicon capital”, steadily advancing plans to build a trillion-yuan photovoltaic industrial cluster and the world’s largest crystalline silicon production base.
The booming new energy sector has become a powerful engine for economic transformation and upgrading across the region. Inner Mongolia’s abundant green electricity not only supports its own high-quality development but also plays a vital role in meeting the country’s overall energy needs.
As one of China’s main energy hubs, Inner Mongolia generates about one-sixth of the country’s total energy output and accounts for one-third of China’s cross-regional energy transmission. In 2025, the region delivered 90 billion kWh of green electricity to other regions, a year-on-year increase of more than 40 percent, bringing clean power across mountains and rivers to light homes and power industries nationwide.
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Independent power producer (IPP) Origis Energy has secured US$545 million in financing for three utility-scale solar projects with a combined capacity of 413MW in Ector County, Texas. 
The Rockhound projects have secured financing from Natixis Corporate & Investment Banking and Santander Corporate & Investment Banking. The package includes senior secured credit facilities comprising construction and term loans, a tax credit bridge facility and letters of credit to support both the build-out and operational phases. 
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The projects are currently under construction and are expected to reach commercial operation later this year. 
“This financing reflects the quality of the Rockhound portfolio and the confidence our capital partners place in Origis’ ability to execute complex, multi-project transactions with discipline and scale,” said Alice Heathcote, chief financial officer, Origis Energy.  
“Natixis and Santander have been exceptional partners throughout the process. Together, we are advancing resilient, long-term energy infrastructure in Texas while delivering meaningful economic benefits to local communities.”  
The financing marks the next stage in Origis Energy’s multi-project solar complex in West Texas, which is expected to exceed 700MW of total capacity once fully completed.  
The wider complex also includes the Swift Air Solar II and Swift Air Solar III projects, both of which reached financial close in 2025. Origis recently commissioned the three 145MW Swift Air solar facilities in West Texas, which will supply power to Occidental’s operations in the region. 
Primoris Renewable Energy served as engineering, procurement and construction (EPC) contractor for the projects. Array Technologies supplied the tracking systems, while Sungrow provided the inverters and Boviet Solar delivered the PV modules. 
Miami, Florida-headquartered Origis has developed more than 5GW of capacity to date and, as of early 2026, has a US pipeline of 11.9GW of solar and over 9.1GW of storage in development, focused on utility-scale projects.  
In Texas, the company has over 1GW of operational or contracted capacity in West Texas. This includes the 303MWdc Greyhound A solar project, developed in partnership with Meta and expected online by mid-2026, alongside a further 413MWdc in Ector County slated for completion in 2026.   
Origis is also advancing more than 1GW of additional solar and storage in the region, supported by over US$2.5 billion in infrastructure investment. 

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Solar panels will look like this in the future — Plasmonic “superballs” made of gold absorb sunlight and make it “explode” to produce energy  Energies Media
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Campaigners have criticised plans for the UK's largest solar farm between Doncaster and Rotherham
New proposals for a large-scale solar farm on land in Rotherham and Doncaster have reduced the overall size of the project – but councillors and MPs remain unconvinced.
Whitestone Solar Farm would be one of the largest in the UK and was originally projected to cover 3,500 acres (5.5sq miles).
No formal planning application has yet been submitted but, following consultations, Whitestone Net Zero Ltd revealed it had reduced the overall size of the project by 17%, compared to original proposals.
However, elected representatives of communities close to the three proposed sites said not enough had been done.
In a newsletter published on the Whitestone Solar Farm website, the developers said they had held eight in-person information events, attended by 718 members of the local community.
The latest proposal includes a 37% reduction in the size of the developable areas within the project, according to the Local Democracy Reporting Service.
However, councillor Rachel Reed, who represents Conisbrough in Doncaster for Reform UK, said: "Whilst any reduction in the proposed Whitestone Solar Farm is welcome, a development of more than 1,100 hectares is still an enormous industrialisation of our countryside."
The company behind the scheme says the revised proposal has downsized the project by 17 percent
Labour MP Jake Richards, who was elected to represent Rother Valley in 2024, said "some acute needs had been met", but added: "It's not close to being enough."
The City of Doncaster Council and Rotherham Metropolitan Borough Council both passed motions in their council chambers opposing the original plans. Doncaster Council had also previously passed a motion, with cross-party support, opposing the development of solar farms on green belt land, stating a preference for brownfield land or rooftops.
Developers said the sites had been selected due to their proximity to Brinsworth substation, which would connect the solar farm to the National Grid and avoid high quality agricultural land.
The project is being developed by Green Nation and Net Zero One who say it would make a significant contribution to national energy goals to reduce energy costs, create energy security and fight against climate change.
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Georgia solar panel maker is returning to full production after a pause  AJC.com
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© 2025 THE COOL DOWN COMPANY. All Rights Reserved. Do not sell or share my personal information. Reach us at hello@thecooldown.com.
“Over the past year I’ve been trying to figure out a better way to deal with more frequent power outages.”
Photo Credit: iStock
Relying on the electric grid means being beholden to the whims of large energy companies. 
One Redditor shared a workaround that saves money on electric bills and keeps the lights on during power outages: solar-powered battery backup.
“Over the past year I’ve been trying to figure out a better way to deal with more frequent power outages,” the user posted to Reddit’s r/SolarDIY community. “I looked into installing a Tesla Powerwall, but it was expensive. So I went with a more affordable setup instead: a portable power station.”
The Redditor explained how they use a solar-powered generator for backup energy during outages. They also noted that the system charges from the grid during off-peak hours when energy is less expensive. It then stores that energy to power household appliances when electricity prices are high, leading to savings compared to grid power alone.
Want to go solar but not sure who to trust? EnergySage has your back with free and transparent quotes from fully vetted providers in your area.
To get started, just answer a few questions about your home — no phone number required. Within a day or two, EnergySage will email you the best options for your needs, and their expert advisers can help you compare quotes and pick a winner.
The user also noted that they plan to maximize their energy savings by installing solar panels. Solar systems, from expansive rooftop setups to backup power stations, are among the best ways to save money on home energy.
If you’re interested in home solar but overwhelmed with the options, EnergySage can help. It offers quick solar installation estimates and lets users compare quotes, so you can get a sense of how quickly your solar investment will start paying for itself.
Solar power is an especially prudent choice in areas prone to frequent power outages, like California.
Pacific Gas and Electric Company, which powers the original poster’s home, occasionally shuts off power to reduce the chance of electric infrastructure starting wildfires. While these outages are necessary, they can be frustrating to homeowners who face sky-high energy costs when the electricity is flowing.
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Want to go solar but not sure who to trust? EnergySage has your back with free and transparent quotes from fully vetted providers that can help you save as much as $10k on installation.
To get started, just answer a few questions about your home — no phone number required. Within a day or two, EnergySage will email you the best local options for your needs, and their expert advisers can help you compare quotes and pick a winner.
One California homeowner installed his own DIY solar panels rather than pay $700 per month in bills to PG&E. Another Redditor went the backup battery route to avoid PG&E’s frequent blackouts.
To get started installing your own battery system and obtain competitive installation estimates, you can explore EnergySage’s home battery storage options.
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The most efficient system is one that combines solar panels with battery storage, and EnergySage can help you make sure you’re getting the best equipment at the lowest price. In fact, with EnergySage’s free services, the average person saves up to $10,000 on solar purchases and installations.
Plus, it helps homeowners take advantage of all the savings available to them by detailing solar incentives for each state. Its mapping tool also shows the average cost of a home solar system on a state-by-state level, providing you with a helpful localized estimate.
💡Go deep on the latest news and trends shaping the residential solar landscape
Commenters on the Reddit post were unsure how much money the OP would save by using battery power during peak hours, but they reiterated the money-saving potential of solar panels.
Some posted photos of their own backyard solar setups. One responded, “I built a solar generator unit just for that.”
Get TCD’s free newsletters for easy tips to save more, waste less, and make smarter choices — and earn up to $5,000 toward clean upgrades in TCD’s exclusive Rewards Club.
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In a new weekly update for pv magazine, Solcast, a DNV company, reports that destabilized polar circulation in February produced wet and cloudy conditions in some parts of North America, while the central and eastern regions enjoyed elevated irradiance under clearer conditions.
Image: Solcast
From pv magazine Global
A combination of stratospheric warming and a disrupted polar vortex produced sharply contrasting irradiance patterns across North America in February, according to analysis using the Solcast API. The destabilized polar circulation produced wetter and cloudier conditions in parts of the north while keeping the central and eastern regions under clearer conditions and elevated irradiance. These opposing patterns created a clear divide in solar performance across the continent, with several inland grids experiencing stronger than normal conditions while coastal regions saw suppressed irradiance.

A major driver of this pattern was stratospheric warming – a rapid warming of the upper atmosphere that disrupts the polar vortex which weakened and disrupted northern circulation patterns during February. This disruption allowed the jet stream to develop waves, shifting storm tracks and cloud distribution across North America. The resulting circulation pattern supported higher irradiance across large portions of the United States despite ongoing winter weather in some regions. Western areas experienced reduced solar resource due to unsettled conditions, while the central and eastern United States saw clearer skies and higher irradiance anomalies.
Opportunities were particularly strong across the ERCOT and ISO-NE grids, where irradiance increases approached 20% alongside unusually high temperatures exceeding 38°C (100° F) in some locations. Even a late-month nor’easter or winter storm that brought heavy snow to the northeastern United States did not significantly reduce the broader pattern of elevated solar conditions. Above-average irradiance extended beyond the United States, reaching from the Rio Grande across east coast of Mexico and southern Quebec.

Despite widespread inland improvements, several coastal regions experienced reduced solar resource due to anomalous weather systems. North and South Carolina recorded around a 15% reduction in irradiance during February as snow and ice events increased cloud cover. Northern California saw similar reductions as a series of atmospheric rivers brought persistent cloudiness and precipitation, suppressing irradiance across the CAISO region. The Appalachian Mountain chain formed a clear boundary between regions of increased and reduced irradiance conditions along parts of the eastern seaboard.
February also marked a step-change in solar conditions compared to January. Across much of the Central and Eastern United States, irradiance patterns supported double-digit solar overperformance, with increases of around 15% to 25% relative to typical February levels. ERCOT stood out within this pattern, where parts of Texas experienced exceptional solar conditions — longer days and seasonal improvements compounded with unusually clear skies to drive irradiance around 25% above seasonal norms, and +40% above January levels, as seen in Dallas, TX.

Solcast produces these figures by tracking clouds and aerosols at 1-2km resolution globally, using satellite data and proprietary AI/ML algorithms. This data is used to drive irradiance models, enabling Solcast to calculate irradiance at high resolution, with typical bias of less than 2%, and also cloud-tracking forecasts. This data is used by more than 350 companies managing over 300 GW of solar assets globally.
The views and opinions expressed in this article are the author’s own, and do not necessarily reflect those held by pv magazine.
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Kaawanui Solar Approved: Kaua‘i Project Clears PUC  Hoodline
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Agrivoltaics: More Than Just Electricity From Field  Mirage News
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Researchers in the U.S. have developed a set of guidelines and protocols to assess the performance of three-terminal (3-T) and four-terminal (4-T) tandem solar cells, including those with subcells made of III–V, CdTe, perovskites or silicon materials.
Image: pv magazine
From pv magazine Global
Researchers from the National Laboratory of the Rockies in the U.S. have formulated a comprehensive performance measurement framework for three-terminal (3-T) and four-terminal (4-T) tandem solar cells.
“Our work introduces the first comprehensive performance measurement framework specifically for three-terminal (3-T) and four-terminal (4-T) tandem solar cells, including perovskite-based devices,” Tao Song, corresponding author of the research told pv magazine, noting that there is a need for reliable and standardized performance-measurements for emerging multi-terminal tandems 3-T and 4-T tandem designs. “We demonstrated practical, validated approaches to ensure that reported efficiencies are accurate, reproducible, and comparable across laboratories and industry,” said Song.
The interest in 3-T and 4-T devices is driven by the potential to reduce subcell current-matching constraints, higher device energy yields, and as an alternative path for combining emerging PV materials like perovskites with established silicon material combinations, such as perovskites and silicon or perovskites and cadmium telluride (CdTe), according to the study.
The researchers illustrated the methods with three different multi-terminal cell configurations, two 3-T devices and one 4-T device. One 3-T was a perovskite/interdigitated-back-contact (IBC) silicon device and the other was a gallium indium phosphide (GaInP)/gallium arsenide (GaAs) device. The 4T device was a GaAs top cell with an IBC silicon bottom cell.
For 3-T tandems, the researchers indicated a straightforward protocol if both subcells are fast response types. But for devices with slow-responding subcells, such as those made with a perovskite absorber, two steady-state methods were described: (i) two-dimensional maximum power point tracking (MPPT) for both subcells, and (ii) a hybrid method combining MPPT on one subcell with an asymptotic stabilized maximum power (PMAX) scan on the other. “Both approaches yield equivalent results but differ in measurement time,” noted the researchers.
For 4-T tandems, the team described two I-V measurement approaches, either synchronized scans with spectrum adjustment or sequential scans with individual irradiance adjustment for each subcell.
“When slow-responding subcells are involved, they must be measured using steady-state methods, while fast-response subcells can be characterized with conventional I–V scans,” explained the researchers, adding that in cases where luminescent coupling exists between subcells, the non-tested subcell must be held at its PMAX “using a proper load resistor to ensure accurate determination of the combined output.”
“We expect this framework will help shape future International Electrotechnical Commission (IEC) and American Society for Testing and Materials (ASTM) standards for multi-terminal tandem devices,” said Song.
Noting that it adapts to both fast and slow-responding materials to properly account for electrical and optical coupling effects between subcells, Song said that the framework is “broadly applicable, not only to perovskite-based tandems, but also to other multi-terminal solar technologies like III–V, CdTe and silicon-based tandems.”
In the conclusion of the study, the team noted that not all research laboratories have access to spectrum-tuning hardware and synchronized scan capabilities. Without such tools, measurement limitations can introduce “non-trivial measurable errors.” As a result, third party testing to establish records and accurate baseline measurements was recommended.
For other cases, a simpler protocol was provided with the caveat that the measurement limitations and potential sources of error should be clearly documented and reported.
“The next step is broader adoption and standardization of these measurement practices. As tandem devices scale toward manufacturing, consistent and trustworthy performance rating will be essential,” said Song. The group is now extending these methods to industrial-scale wafers and modules, supporting the development of future international standards for tandem PV testing.
The research work is detailed in “Performance measurement of emerging 3- and 4-terminal tandem solar cells,” published by EES Solar. A team from Centre suisse d’électronique et de microtechnique (CSEM) also participated in the study.
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Twelve photovoltaic storage systems with capacities of 5 kW or 10 kW were included in the comparison, among them several new products, all of which achieved efficiency class A. A new study – also examining efficiency losses when storing electricity from the grid – highlights the importance of highly efficient battery storage. The researchers also took a closer look at the warranty conditions of the devices.
Image: Fox ESS
From ESS News
Fox ESS is the new test winner in the “Energy Storage Inspection,” which the Berlin University of Applied Sciences (HTW Berlin) conducted for the first time in cooperation with Aquu. Aquu is an HTW spin-off founded by Johannes Weniger, who previously oversaw the university’s annual storage inspection.
This year, a total of twelve photovoltaic storage systems competed in four different categories. The evaluation was carried out separately for 5 kW and 10 kW products, with further differentiation between AC- and DC-coupled systems. To ensure comparability, the results were assessed using the System Performance Index (SPI).
Fox ESS’s 10 kW DC system achieved a new record with an SPI of 97%. According to the test results published on Thursday, this made it 3.5 times more efficient than the lowest-performing system in the comparison. The storage system, equipped with the 10 kW hybrid inverter “PQ-H3-Ultra-10.0,” impressed the testers with a very high average efficiency of 97.6% and low standby power consumption of just 4 watts.
However, storage systems from RCT Power, Energy Depot, Fronius, and Kostal (DC) in combination with BYD also achieved SPI scores above 95%, earning efficiency class A. The Kostal AC system combined with BYD narrowly missed this threshold with 94.3% and was assigned efficiency class B.
Two other tested systems performed significantly worse, achieving SPIs of 91.9% (efficiency class D) and 89.3% (efficiency class G). Their manufacturers opted for anonymized publication of the results. The testers attributed the weaker performance of one system to high losses in the battery storage unit and a large standby power consumption of 64 watts, which negatively affected overall system efficiency.
In the 5 kW category, the inspection again differentiated between DC- and AC-coupled systems. SAX Power’s multi-level system took the lead in this class with an SPI of 93.2%, making it the test winner among AC devices.
Among systems with hybrid inverters, SMA once again achieved the highest score, reaching 92.8% with its “Sunny Boy Smart Energy 5.0” paired with the “Home Storage 6.5” battery. Close behind was the Kostal and BYD combination, tested for the first time, with an SPI of 92.7%.
For next year, the testers announced the introduction of a 15 kW storage inspection. Manufacturers offering battery systems with storage capacities between 16 and 24 kWh will be able to participate.
“The registration phase is now open: manufacturers of AC- and DC-coupled storage systems with battery and hybrid inverters can register immediately to participate in the new 15 kW storage test,” said Johannes Weniger, founder and CEO of Aquu.
However, the researchers are not only expanding the scope in terms of performance classes. Last year they examined energy management systems for the first time, and this year the scientists investigated how low storage losses must be for charging batteries with grid electricity—such as under dynamic tariffs—to be financially viable.
According to Weniger, the decisive factor is conversion losses. The researchers illustrated this with a typical winter scenario in which a battery is charged overnight with grid electricity at €0.25/kWh and the stored energy is used in the evening when electricity costs €0.35/kWh.
“In this case, storing grid electricity is only advantageous for the household if inverter and battery losses are below 29%,” the authors of the Storage Inspection explained. In other words, the overall system efficiency must exceed 71% for the strategy to be worthwhile.
The test results showed that not all battery storage systems reach this threshold. “The price difference between charging and discharging periods is often not large enough to compensate for the losses of the battery system,” explained Nico Orth, head of the electricity storage inspection at HTW Berlin.
The study provides further details on the maximum permissible conversion losses under different electricity price scenarios.
In addition to efficiency, the testers also examined the warranty conditions of 20 well-known manufacturers, revealing some significant differences. For example, the guaranteed remaining battery capacity during the warranty period ranged from 60% to 85%, with higher values being more advantageous for storage system operators.
However, unpleasant surprises can arise in the event of damage, making it important to carefully review the fine print. “Favorable warranty conditions can often be recognized by the fact that the manufacturer does not impose extensive documentation requirements and covers the cost of replacement in the event of a defect,” said Nico Orth.
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The New Jersey Board of Public Utilities action fulfills Governor Sherrill’s recent executive mandate, launching the largest-ever solicitation for distributed generation in New Jersey history.
A New Jersey warehouse with Qcells solar panels installed.
Image: pv magazine USA
The New Jersey Board of Public Utilities (NJBPU) approved an unprecedented 3 GW scale-up of the Community Solar Energy Program (CSEP) and awarded incentives for the first tranche of the Garden State Energy Storage Program (GSESP).  
The actions follow a 45-day sprint triggered by Governor Mikie Sherrill’s Day One executive orders aimed at decoupling state energy prices from a volatile PJM wholesale market. 
The Board’s March 4 session marks a fundamental pivot toward “speed to market” as the state grapples with a $16 billion surge in PJM capacity costs and escalating load growth from the data center sector. 
The NJBPU awarded incentives to three large-scale battery projects under GSESP Phase 1, Tranche 1. The awards represent 355 MW of nameplate capacity, surpassing the 350 MW minimum set by state mandate. 
The winning projects include: 
Simultaneously, the Board launched Tranche 2 of the program, seeking an additional 645 MW of storage capacity. Pre-qualification materials are due by June 10, 2026. This second tranche is specifically designed to bridge the gap between stand-alone assets and solar-plus-storage configurations that may not fit the existing Successor Solar Incentive (SuSI) framework. 
Perhaps the most significant development for distributed energy resource advocates is the formal opening of a 3 GW block for community solar. This capacity is designed to reach approximately 450,000 subscribers, with a mandatory 51% allocation for low-to-moderate income households. 
The board distributed the capacity across the state’s four major investor-owned utilities based on retail sales: 
The Board also opened the Fourth Solicitation of the Competitive Solar Incentive (CSI) program. A notable shift in this round is the creation of Tranche 1A, a dedicated competitive bucket for basic grid-supply projects exceeding 20 MW. The solicitation also introduces a paired storage “adder” for large net-metered facilities, signaling the BPU’s intent to make every new MW of generation as flexible as possible to mitigate peak demand. 
While the BPU has greenlit the capacity, the industry remains focused on how to implement it while facing interconnection bottlenecks. The Board concurrently issued a Request for Information to the state’s utilities, demanding data on circuit-level constraints and asking for specific recommendations on how to waive or modify existing regulations to speed up interconnection. 
“Solar and battery storage are the fastest and most cost-effective ways to build new electricity generation,” said NJBPU President Christine Guhl-Sadovy. 
With pre-qualification for the next round of utility-scale bids opening March 11, the state’s developers are now in a race to secure equipment and interconnection spots before the July 4, 2026, safe-harbor deadlines for federal tax credits.
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French energy major TotalEnergies has initiated pilot operations of the first generating unit at its 1GW solar farm in Iraq’s Basra region. 
Pilot commissioning has begun for the first 61MW unit, which will be gradually ramped up to its full 250MW capacity. The unit will be connected to the national grid via the New Rumaila and Souq Al Shuyoukh transmission lines, following technical plans prepared by the project’s engineering and supervisory teams. 
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The company said the project is Iraq’s largest solar installation, comprising four 250MW units. Spanning nine kilometres, it will feature two million solar panels across the four units. 
The Director General highlighted that bringing the first unit into trial operation marks a key milestone for both the company and the Ministry, underlining the project’s importance in diversifying Iraq’s power mix, particularly in Basra Governorate, where electricity demand is rapidly rising. 
Announced in 2021, Basra solar farm is the second 1GW solar plant in the country built by TotalEnergies, with a US$10 billion investment in new gas networks and seawater treatment.   
The project entails the installation of 132kV transmission lines spanning a total length of 180km, the construction of a new 132kV substation, and the rehabilitation and modernization of two existing substations under the ministry’s jurisdiction.  
Additionally, TotalEnergies will manage operation and maintenance (O&M) for the project over a 25-year period. The solar farm will supply electricity to three secondary substations. 
The plant is being built in partnership with Iraq’s Ministry of Oil announced in March 2021. In 2023, state-owned power company QatarEnergy entered as a third party with a 25% stake in the project. During the same period, Total confirmed Saudi energy provider ACWA Power would assist in developing the solar project. 
In 2024, Iraq announced plans to deploy 12GW of solar PV capacity by 2030, according to the Iraqi National Investment Authority. Adviser Rahim Al-Jaafari said the Authority had begun issuing investment licenses, with around 7.5GW already allocated by the Council of Ministers and steps underway to assign the remaining capacity.

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Spanish postal operator Correos is expanding its rollout of additional solar photovoltaic plants across Spain under its Correos Solar programme.
Five new self-consumption solar installations are being deployed at major Automated Treatment Centres (CTAs) in Barcelona, Alicante, Valencia and Seville. Facilities at Sant Cugat del Vallès (450kWp) and Barcelona Colón (93.74kWp) will join new plants in Alicante (400kWp), Valencia (455kWp) and Seville (528kWp). On average, Correos said the installations are expected to generate around 22% of the electricity consumed at these logistics centres.
Correos launched its solar programme in 2022 with a photovoltaic installation at its largest logistics facility in Madrid. The site has 960 solar panels with a total installed capacity of 518kWp and produces an average of more than 719,000kWh of renewable electricity annually, covering around 22% of the site’s energy demand.
A second phase of expansion is already underway, with six further installations planned before the end of 2026 in Las Palmas, Santa Cruz de Tenerife, Málaga, Palma de Mallorca, Vitoria and the Madrid International Exchange Office. Together, these projects are expected to supply approximately 29% of the energy consumed at those sites.
By the end of the year, Correos said it expects to operate 12 large solar PV facilities with a combined installed capacity of 4,255kWp. Annual production is projected at between 5.5 million and 6.8 million kWh, equivalent to the electricity consumption of roughly 1,500–2,000 households.
The solar rollout forms part of a broader energy transition programme. Since 2018, all electricity purchased by Correos has come from certified renewable sources, avoiding around 24,000 tonnes of CO₂ emissions annually.
Correos is also electrifying its delivery fleet and has deployed more than 3,200 charging points for electric vehicles across Spain.
For three years, the Sustainable Supply Chain Conference led the conversation on sustainable operations. Now, they’re raising the bar.
The Responsible Supply Chain Conference, taking place in London on 23 June embodies a commitment to holistic, accountable, and ethical value chains.
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Danantara Announces Plan To Build Solar Panel Factory In Indonesia  SolarQuarter
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Babilonia has a power purchase agreement with Grupo Unacem’s energy commercialisation and generation affiliate Celepsa. Babilonia is part of the 700MW La Joya renewables complex, which includes the operational 300MW San Martin solar project and another 125MW advanced development-stage scheme. Construction started in February. 
Zelestra, owned by Swedish private equity firm EQT, plans to invest at least US$1bn in renewable plants over the next five years, powering mines in copper-rich southern Peru. 
Zelestra is quite active in project finance in the region and also recently closed a US$282m green project finance package backing the 220MW/1GWh Aurora solar and storage project in Tarapaca, Chile. Natixis and BNP Paribas were lenders to that deal, and BCI provided a VAT facility. 
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Sunsure Energy has secured 8 MWp of solar power agreements to supply clean energy to the Tamil Nadu facilities of South Korean automotive companies.
A solar project by Sunsure Energy
Sunsure Energy
Sunsure Energy has signed long-term solar power purchase agreements (PPA) with Daeseung Autoparts India, Indian subsidiary of South Korea–based automotive components company Daeseung Group, and Ilgahng Automotive, a Korean-origin automotive company from the same business group.
Under the agreement with Daeseung, Sunsure Energy will supply approximately 8 million units of power annually to Daeseung’s Kanchipuram facility from its 75 MWp solar plant at Ilayangudi, Tamil Nadu. This will allow Daeseung Autoparts India to meet close to 60% of its total power demand with renewable energy, offsetting approximately 5,800 metric tonnes of CO₂e emissions per year.
Similarly, Sunsure will supply approximately 4.7 million units of power to Ilgahng Automotive’s Kanchipuram facility from its Ilayangudi solar plant. This will help Ilgahng offset 3,400 metric tonnes of CO₂e emissions per year.
In Tamil Nadu, Sunsure has a development pipeline of over 1,100 MW of RTC renewable energy capacity across solar, wind and BESS.
Founded in 2014, Sunsure Energy has wind, solar, and energy storage plants across multiple states in India, supplying round-the-clock renewable energy to C&I customers. It is backed by Partners Group AG with an equity commitment of $400 million towards its vision of building the largest industrial decarbonisation company in India and Southeast Asia. Sunsure has 700 MW operational assets with an additional 7.10 GW under various stages of development across Maharashtra, Uttar Pradesh, Tamil Nadu, Rajasthan, and Karnataka. It targets 10 GW RE capacity by 2030.
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The nation’s second-largest solar module manufacturer has returned to normal production levels following the release of component shipments that had been stalled by U.S. Customs and Border Protection.
The Qcells solar panel manufacturing facility in Dalton, Ga.
Image: Qcells
Qcells, the U.S. solar manufacturing arm of South Korea’s Hanwha Solutions, announced it has officially returned to normal solar panel production at its manufacturing facilities in Georgia.
The increased volume of production closes a chapter for the manufacturer’s U.S. operations. In November, the company announced a furlough of 1,000 of its workers due to a temporary pause in production caused by a lengthy customs clearance process.
“We are proud to be back to work manufacturing the American-made energy the country needs right now,” said Marta Stoepker, head of communications at Qcells. “Like any company, hurdles have and will occur, which requires us to adapt and be nimble, but our overall goal remains the same — to build a complete American solar supply chain.”
At the time of the furlough, the company cited significant delays at U.S. ports, which held up seven shipments of solar cells from South Korea. The supply chain bottlenecks began earlier in the year when U.S. Customs and Border Protection (CBP) initiated detentions of Qcells’ solar cell imports under the Uyghur Forced Labor Prevention Act (UFLPA). 
In August 2025, Qcells confirmed the detentions but issued statements of its certainty that its supply chain was free from material originating from the Xinjiang Region that is the subject of the UFLPA.
At the time of the furloughs, Qcells noted that most of its shipments were clearing customs, but the compounding delays had already forced the temporary reduction in production capacity.
Now, with the supply chain flowing and employees back to work, Qcells is pushing forward with the $2.5 billion expansion of its Cartesville plant, which is projected to allow for 3.3 GW of capacity for manufacturing ingots, wafers, and cells by the end of 2026.
At full capacity, the two Georgia facilities will produce a combined 8.4 GW of solar panels and components annually. To meet these targets, the company plans to continue expanding its newly returned workforce. By the end of 2026, Qcells said it expects to employ a combined workforce of nearly 4,000 people across the two sites.
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The Global

Hybrid Solar Wind Systems Market, valued at

USD 1.2 billion in 2024, is projected to reach USD 2.3 billion by 2034, growing at a CAGR of 6.7% from 2025 to 2034. The Asia Pacific region led the market in 2024, holding a 43.8% share worth approximately USD 0.5 billion.

Hybrid Solar Wind Systems combine solar photovoltaic (PV) panels and wind turbines to deliver reliable electricity. By leveraging the complementary nature of solar energy — generated primarily during the day — and wind energy — often stronger at night or under overcast conditions — these systems provide consistent power output, reducing dependence on diesel generators or grid electricity, particularly in remote and off-grid areas.

The market is expanding steadily, driven by the global push for sustainable, decentralized energy solutions. Rising electricity demand in rural areas, where grid expansion is costly or impractical, has increased the appeal of hybrid systems. Supportive government policies and clean energy targets across both developing and developed nations are further accelerating growth, alongside significant reductions in the cost of solar panels, wind turbines, and battery storage.

Stricter environmental regulations and climate change commitments are also key catalysts. As countries work to cut carbon emissions and transition away from fossil fuels, hybrid systems are becoming increasingly central to rural electrification, microgrid development, and disaster-resilient infrastructure. Notable recent investments include Tata Power securing USD 4.25 billion from the Asian Development Bank for clean energy projects, and ACME Renewtech receiving ₹19.88 billion in financing for a 300 MW wind-solar hybrid project.

Key Takeaways

Market Segments

By Component

Solar PV Panels led the component segment in 2024 with a 38.4% share. Their dominance reflects high efficiency, falling costs, and seamless integration with wind turbines and storage systems. PV panels perform particularly well in sun-rich regions, providing consistent daytime power that complements the variability of wind energy. Their modular design suits applications ranging from small residential installations to large commercial off-grid projects, and ongoing advances in cell efficiency ensure solar PV remains central to hybrid energy infrastructure.

By Connectivity

On-grid systems held a 63.1% share of the connectivity segment in 2024, favored in urban and semi-urban areas with reliable grid infrastructure. These systems blend renewable generation with grid electricity, optimize energy usage, and allow excess power to be fed back to the grid — reducing costs and ensuring supply stability during peak demand or adverse weather. Net metering policies and government incentives have further accelerated their adoption across commercial, industrial, and residential sectors.

By End Use

The commercial sector accounted for 44.2% of hybrid solar wind installations in 2024. Offices, retail chains, hospitals, and data centers are increasingly turning to these systems for reliable, cost-effective power. Rising energy costs, carbon reduction pressures, available rooftop space, and favorable government incentives — including tax benefits — are all driving commercial adoption. As businesses continue to prioritize energy resilience and sustainability, the commercial sector is well positioned to maintain its market leadership.

Regional Analysis

Asia Pacific dominated the global market in 2024, commanding a 43.8% share valued at USD 0.5 billion. Growth is supported by favorable government policies, rural electrification programs, and strong demand for decentralized energy in countries such as India and China. The region's abundant solar and wind resources further boost hybrid system deployments in off-grid and semi-urban settings.

North America and Europe remain significant markets, with a focus on sustainability and grid modernization, though both trail Asia Pacific in overall scale. The Middle East, Africa, and Latin America are emerging as growth regions, with rising interest in hybrid solutions for remote communities, supported by pilot projects and international funding.

Top Use Cases

Notable Company Developments

Conclusion

Hybrid Solar Wind Systems are reshaping energy access by delivering reliable, sustainable power across a wide range of applications. As technology matures and costs continue to fall, these systems are set to play an increasingly important role in rural electrification, commercial sustainability, and resilient infrastructure — contributing to a cleaner, more decentralized global energy future.
I am blogger, digital marketing pro since 5 years and writes for Market.us. Computer Engineer by profession. I love to find new ideas that improve websites' SEO. He enjoys sharing knowledge and information about many topics.

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Overview The Global Flywheel Energy Storage Systems (FESS) Market is on a robust growth trajectory, with projections indicating a rise from USD 412.3 million in 2024 to USD 1,003.3 million by 2034. This expansion represents a steady CAGR of 9.3% throughout the forecast period from 2025 to 2034. A significant catalyst for this growth is North America's USD 204.9 million investment in grid modernization, which has substantially accelerated the adoption of advanced FESS technologies.

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Apple just shattered its traditional release cadence with a "Cupertino Whirlwind"—a relentless three-day barrage of product announcements that has fundamentally disrupted the company’s hardware and pricing hierarchy. Starting with the budget-conscious iPhone 17E and culminating in the shock release of the MacBook Neo, this flurry was more than a series of updates; it was a calculated market offensive. With everything hitting shelves on March 11, the speed of these releases signals a pivotal shift in how Apple intends to capture the next generation of users.
By Mohammad Hamidabout 7 hours ago in Futurism
AI Agents Market Overview The global AI Agents Market is experiencing strong expansion as organizations adopt intelligent automation tools capable of performing complex tasks with minimal human intervention. The market is projected to reach USD 139.12 Billion by 2033, rising from USD 3.66 Billion in 2023, which reflects a significant CAGR of 43.88% during 2024 to 2033. In 2023, North America accounted for the leading regional position, capturing more than 37.92% of the total market share and generating approximately USD 1.3 Billion in revenue. The rapid adoption of artificial intelligence, increasing enterprise automation initiatives, and expansion of cloud computing infrastructure are contributing to this strong market growth.
By Roberto Crumabout 14 hours ago in Futurism
As one of the biggest properties in fantasy, A Song of Ice and Fire remains immensely popular with audiences. After reaching far into the past with House of the Dragon, a second spin-off was on the cards. A Knight of the Seven Kingdoms serves up a bite-sized slice of action and drama, but it still claims a spot among the best small-screen titles.
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All solar panels degrade over time, but expert installation and regular maintenance can prevent an early sunset on their lifespan
Change by degrees offers life hacks and sustainable living tips each Saturday to help reduce your household’s carbon footprint
Got a question or tip for reducing household emissions? Email us at changebydegrees@theguardian.com
Across Australian rooftops, a quiet renewable energy revolution has been gathering pace. Australia’s Energy Market Operator described the last three months of last year as a “landmark moment”, with renewables’ energy share rising above 50% for the first time.
Australia has for many years had the highest penetration of household solar panels in the world, with about 4.3m homes – roughly one in three – having installed rooftop solar, with a capacity exceeding 28GW.
But as more households embrace renewable power, a recent University of New South Wales study has found solar panels are also failing faster than expected. This raises questions about what to look for when shopping for solar for your home or business, and how best to maintain panels in increasingly volatile and extreme weather conditions.
Like most manufactured products, solar panels will degrade over time. But when a team from the UNSW school of photovoltaic and renewable energy engineering analysed 11,000 photovoltaic samples, they concluded that around one in five performed 1.5 times worse than expected.
This implies that instead of the 25-year expected lifespan, 20% of panels will start to fail after just 12 years. Key problems identified include internal failures due to panel elements interacting with each other, poor quality control resulting in manufacturing defects, and other flaws that result in performance loss over time.
“For the entire dataset, we observed that system performance typically declines by around 0.9% per year. However, our findings show extreme degradation rates in some of the systems,” said Yang Tang, one of the research authors, in a press statement last month. “This means that for some systems … they could lose about 45% of their output by the 25-year mark.”
Everyone’s experience with solar panels will differ, but simple home maintenance strategies can increase their longevity. Tim Forcey, the author of My Efficient Electric Home Handbook, had solar panels installed in his Melbourne bayside home in 2008 and says while he kept them as “a bit of a science experiment”, they are still working. He added 22 more panels in 2017 that now provide all his home’s electricity needs.
Forcey says during a wild hailstorm last year that destroyed a sheet of plastic over his patio, the solar panels survived. He says one simple tip is to install the panels at an angle so they don’t accumulate and hold too much water and mud. “I keep them clean with a brush on a long stick, especially taking care to get rid of any moss and lichen that accumulates.”
Brendan Lang, an electrician and founder of Get Off Gas, says there are three important things that people can do to minimise the risks of their panels not meeting expectations: using quality products from the start, getting expert local installers on board and regular maintenance.
“You wouldn’t expect your motor vehicle to be running perfectly after 25 years if you didn’t service it – same goes for renewable energy.” Lang recommends having a qualified expert guide you through the installation process and come back to service your panels every two to three years.
“Systems come in many varieties of quality and therefore serviceability and longevity. Good maintenance is vital for safety as well as efficiency and longevity. Keeping your panels clean, cabling and connections in check, and ensuring the racking affixing the panels to your roof is fastened are all equally important,” Lang says.
The other advantage of regular servicing is that it will allow you to monitor your panels’ performance. If the performance markedly drops, you can make a claim under warranty (usually 25 years on quality panels).
All solar panels have a limited lifespan, but there are many factors to take into account when considering whether to repair or replace your existing unit.
If only one of your solar panels fails, you may be able to find a suitable replacement, advises Finn Peacock of Solar Quotes, but it must have very similar physical size and specifications to be suitable. If it’s a problem with your inverter, secondhand inverters are widely available, and a good installer can replace it for you.
“A good original installer will install one type of panel and likely keep spares or be able to get them from the manufacturer,” Peacock says. “As a last resort, you may be able to just remove the panel, or bypass it electrically – depending on the string configuration. You’ll lose one panel worth of energy (about 2kWh per day) but keep the rest of the system going for minimal cost.”
If your system is more than about six years old, replacing the whole array will get you much more efficient panels, producing more energy, and you may be able to claim the solar panel rebate again, Peacock says.
If you do need to replace your panels, make sure you get them properly recycled.
“Don’t assume the people removing them will recycle them – because it costs $30 per panel to do it, they unfortunately often end up elsewhere,” he says. “You need to insist on it and ask for the receipt.”
Peacock says simple things like avoiding permanent shade, regular servicing and ensuring leaves don’t build up underneath will give your panels the best chance of longevity.

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Colorado could soon see a new wave of home solar power — but not in the form of the large solar panels you may see on rooftops around your neighborhood. Instead: Imagine slim, portable panels that you can attach to a porch or balcony and then plug into your wall.
Small-scale solar units like these are already popular in Europe. But they’re almost unheard of in the U.S., partly because of regulatory restrictions by power utilities but also because there aren’t many of these plug-in solar products on the market.
Not yet, at least.
A bill at the Colorado statehouse could clear the way for renters, condo owners and people who can’t afford a full rooftop system to buy these plug-in panels.
State lawmakers hope to see these systems available by the end of this year.
Reporter Michael Booth covers the environment for The Colorado Sun. He spoke with Erin O’Toole about how these tiny solar power units work, and how this might look in Colorado.

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Saturday, March 7, 2026
The final panel has been installed at Australia’s first large scale solar-battery hybrid facility to connect to the main grid, heralding a radical change in the make-up and shape of the country’s electricity system.
The $192 million Quorn Park Hybrid Solar facility – near Parkes in western NSW – combines 80 megawatts (MW) of PV generating capacity with a 20 MW, 40 megawatt-hour (MWh) battery behind the same connection point.
Developer, Potentia Energy, this week announced its contractor, Beon Energy Solutions, had installaed the final solar panel at Quorn Park – a “major milestone” at what is a milestone project.
“After six months of work, nearly 161,000 panels are now in place at the site near Parkes, NSW, a significant moment towards delivering one of Australia’s most advanced hybrid renewable energy projects,” Potentia said on LinkedIn.

Pontentia says Quorn Park has also had a meaningful local impact, with 63 per cent of the mechanical workforce at sourced locally at the time of peak construction. Through the Women in Solar pre-employment program, around 30 per cent of the workforce has been women.
Image: Potentia Energy
“Due for completion in late 2026, Quorn Park will be the first large-scale solar and battery hybrid power plant connected to Australia’s main grid,” Potentia says.
“By storing solar energy generated during the day and dispatching it during evening peaks, the project will strengthen grid reliability while delivering enough clean energy to power around 45,000 homes in NSW every year.”
As Renew Economy explains here, solar farms and battery projects have often been built side by side, but with separate connection points so they operate independently, which means they have to accept market prices for charging (in the case of the battery), and exporting (in the case of the solar and the battery).
The fact that they can now be accommodated behind the same meter is due to a lot of work changing Australia’s strict grid connection rules, and has presented as many complexities as the introduction of big batteries nearly a decade ago, and grid forming inverters in recent years.
Quorn Park started injecting small amounts of power into the National Electricity Market last month, doing so up until 8pm at that time. It expected to be able to send power to the grid even later in the evening when fully commissioned, and if needed and the market signals are right.
If you would like to join more than 29,000 others and get the latest clean energy news delivered straight to your inbox, for free, please click here to subscribe to our free daily newsletter.
Sophie is editor of Renew Economy and editor of its sister site, One Step Off The Grid . She is the co-host of the Solar Insiders Podcast. Sophie has been writing about clean energy for more than a decade.
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Photo: ZEZ
Published
March 6, 2026
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Croatia
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Vladimir Spasić
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Published:
March 6, 2026
Country:
Croatia
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Vladimir Spasić
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The 100 kW photovoltaic plant, installed during the first phase of the project, has just been approved for permanent operation, according to the Green Energy Cooperative (ZEZ), which is implementing the project.
The solarization of SOS Children’s Village Lekenik is being implemented in two phases, based on a EUR 340,000 donation agreement signed in July last year between SOS Children’s Village Croatia, Raiffeisen Bank, ZEZ, Biomasa Group, and Kufner Group.
The first phase involved setting up a 100 kW PV plant on the roof of the community center. In the second phase, later this year, an additional 250 kW solar power plant will be installed on the roofs of all 15 family houses where SOS mothers and children live.
ZEZ: This is the first such project in this part of Europe
Upon completion of the project, SOS Children’s Village Lekenik will become children’s first solar village in Croatia and the first project of its kind in this part of Europe, ZEZ underscored.
SOS Children’s Village Lekenik was spending more than EUR 80,000 annually on energy bills. Therefore, the project is a key step toward energy independence and long-term financial sustainability.
With the completion of the second phase, expected savings over the plant’s minimum 25-year lifespan are estimated at EUR 1.17 million, according to ZEZ’s assesment.
These funds will be used for the care and improvement of the children’s quality of life through additional educational programs, summer vacations, foreign language learning, and other activities for enriching their upbringing, the group added.
“ZEZ’s motto is that energy should be in the hands of citizens and the local communities. This project clearly demonstrates that. In a time of climate crisis and energy price volatility, we are sending a message that energy should be renewable and produced locally,” ZEZ director Zoran Kordić stressed.
He pointed out that the ZEZ team demonstrated it can implement large-scale projects, from the initial idea to putting a power plant online.
It is much more than an energy or environmental project; it is also a powerful financial sustainability mechanism for non-profit organizations, according to the organization.
The solarization of SOS Children’s Village Lekenik unites social care, energy transition, and local development, and can serve as a model for other communities in Croatia and the region, ZEZ added.
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Croatia
06 March 2026 – SOS Children’s Village Lekenik, located between cities of Zagreb and Sisak, has installed a 100 kW solar power plant
Romania
06 March 2026 – Several companies achieved progress in their projects for large battery energy storage systems in Romania, both for colocated and standalone facilities
Bosnia and Herzegovina
06 March 2026 – Aleksandar Milić, CEO of Elektrane Stanari, said the surplus electricity the company used to export is now sold on the domestic market
North Macedonia
06 March 2026 – EBRD and IFC expressed willingness to provide a long-term loan for Alcazar Energy Partners’ Štip wind power project in North Macedonia
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Cloudy. Slight chance of an afternoon shower. High 62F. Winds S at 10 to 15 mph..
Cloudy skies early, then partly cloudy after midnight. Low around 55F. Winds S at 10 to 20 mph.
Updated: March 6, 2026 @ 12:54 pm
Property owners near a proposed solar farm look at the site and grading plan for the proposed facility, to be located between South Shady Avenue to the west, Sample Flats Road to the east, Stewart Road to the south and Route 426 to the north.
Representing Greenwood Sustainable Infrastructure, Kevin Johnson speaks to Corry’s planning commission members.

Property owners near a proposed solar farm look at the site and grading plan for the proposed facility, to be located between South Shady Avenue to the west, Sample Flats Road to the east, Stewart Road to the south and Route 426 to the north.
Neighbors cite property values, glare,
environmental concerns over proposed solar array
 
A proposal to build a three-megawatt solar panel array on a residential tract of land near South Shady Avenue has drawn opposition from neighbors and a split vote from the Corry Planning Commission, which narrowly declined to recommend approval to Corry City Council by a 3-2 margin.
Greenwood Sustainable Infrastructure, of New York, N.Y., represented by attorney Kevin Johnson, submitted its conditional use application in December 2024, supplemented in January 2025, seeking permission to install around 5,000 solar panels across roughly 16 acres of R-1 zoned land. The project, described by its developers as small-scale and community-oriented, has nonetheless ignited debate over zoning law, property values, environmental risk and the future character of Corry’s remaining undeveloped land.
Johnson was careful to distinguish the project from large-scale industrial solar farms. 
“Industrial solar projects are 100 megawatts — hundreds of acres, large tracts of land,” he told the commission. “This is a local, community-sized solar project.” 
He noted that Pennsylvania lacks a formal community solar program and argued the development is analogous to those that exist in other states, situated well back from property lines and designed to have minimal environmental impact.
The company proposed to lease the land from its private owner, who Johnson said has every legal right to enter such a contract. The array would be located in the central portion of the site, with vegetative buffering along the perimeter where natural vegetation does not already exist. Greenwood’s project development associate, Annika Shiffer-Delegard, emphasized that no land clearing or significant grading is planned, and that modern solar panels are substantially safer and less reflective than those from earlier decades.
Numerous residents spoke up to oppose the project, raising concerns ranging from declining property values to glint and glare, chemical runoff, radon exposure from soil disruption and the permanent loss of one of Corry’s last large, undeveloped parcels.
Dennis Anderson, a 37-year resident of South Shady Avenue, spoke of raising his family in what he described as a quiet, country setting within city limits. 
“We don’t want [that] to change,” Anderson said. “I don’t need my property values to go down.”
Kurt Lund, another long-time resident, pointed to a glint and glare study commissioned by Greenwood itself, which identified his property as one of the locations most likely to experience solar reflection. 
“Trees at our elevation are not going to mitigate that,” Lund said, adding that he is concerned about the long-term environmental fate of the panels. “When these are still there, leaching into the ground and causing damage to local wetlands, and nobody wants to take them in the landfill, we’re stuck with them.”
Katie Krasa, who moved to the area three years ago specifically for its natural setting, offered detailed arguments. She raised concerns about radon exposure from soil disturbance — noting that her own home required a mitigation system after elevated levels were discovered during her home inspection — and argued that the project conflicts with both the letter and intent of Corry’s zoning ordinances.
“This project threatens property values, conflicts with the purpose of zoning regulations, eliminates one of Corry’s last major opportunities for thoughtful residential or community development and introduces environmental and public health risks,” Krasa said. 
She was followed by Gina Lund, who told the commission, “I agree with every sentence Katie Krasa just said.”
Perhaps the sharpest exchange of the evening centered on whether the city’s 1991 zoning ordinance — which predates solar technology — permits the project at all. Nick Krasa walked the commission through the ordinance section by section, arguing that solar farms are neither expressly listed nor logically implied as a permitted or conditional use in the R-1 single-family residential district.
Representing Greenwood Sustainable Infrastructure, Kevin Johnson speaks to Corry’s planning commission members.
“It does not make sense to interpret R-1 to allow an industrial solar farm,” Krasa said. “Solar farms are not residential in nature and should not be considered special residential projects. They should be treated as either a planned commercial use or an industrial use — neither of which are allowed in R-1.”
Johnson countered that the ordinance allows a wide range of non-residential conditional uses in R-1, including hospitals, nursing homes, colleges, funeral homes and cemeteries. He argued that approving the project as a special residential and commercial use is legally consistent with this framework, and that the city directed Greenwood to proceed under that classification. He acknowledged that generalized objections — concerns about aesthetics, speculative property value impacts or preferences for alternative uses — do not, under Pennsylvania law, constitute sufficient grounds for rejection.
Kelly Goodsel, a resident whose property straddles the city and Concord Township boundary, pushed back. 
“The list of conditional uses — hospitals and playgrounds and things like that — are actually listed in the ordinance. In 1991, solar panels were not part of the ordinance, so they weren’t noted.” 
Goodsel also criticized Greenwood’s buffering proposal for focusing primarily on the western, city-facing edge of the property, leaving residents in Concord Township and Warren County with little protection.
The commission also heard debate over draft special conditions. Johnson said Greenwood could comply with the vast majority of them, but raised two specific concerns. First, he argued that language requiring the project to be visually screened is being interpreted incorrectly as requiring the array to be entirely invisible — a standard he called neither achievable nor appropriate. Second, he objected to construction noise limits expressed as decibel thresholds, proposing instead that construction simply be restricted to daytime hours, suggesting a window of 7 a.m. to 7 p.m.
On the glare issue, Shiffer-Delegard cited an engineering study finding only minimal “green level” glare from most observation points, including a total of 16 minutes per year at the Lund residence during May and June. She described modern anti-glare coatings as standard technology that makes significant reflection unlikely. On the question of weed management, she confirmed that a local operations and maintenance technician would be hired to mow regularly.
After deliberating outside Council chambers, the commission returned with a divided vote. Jim Myers moved to recommend approval to City Council; Scott Johnson seconded. But commission members Bill Wilt, Erica Helmer-Allen, and Tim Gould voted against, resulting in a 3-2 decision not to recommend the project.
City Solicitor Lydia Caparosa reminded residents that the planning commission functions only as a recommending body. Regardless of its vote, the application will still go before City Council at a public hearing to be advertised separately, where both residents and the applicant will again have an opportunity to speak. Council has not set a timeline for its final decision.
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A historical swimming pool once heated by steam from a neighbouring chocolate factory has had solar panels installed to help cut running costs.
The 182kWh roof panels at York's Yearsley Swimming Pool, which has hosted dippers for 116 years, are said be able to save about £23,000 from annual running costs while cutting CO2 emissions by 29 tonnes.
The pool, currently heated by gas, once used steam supplied by the neighbouring Rowntree's Chocolate Factory, now Nestlé UK Ltd.
Paul Bickle, York partnership manager for GLL Ltd, which runs the city's four leisure centres, said the technology would protect the pool's future.

Pete Kilbane, deputy leader of York City Council, told the Local Democracy Reporting Service that pools were expensive to run but vital to support people's health and wellbeing and Yearsley was much-loved by the local community.
A bigger set of panels than needed at the moment has been fitted to accommodate future efforts to decarbonise, the authority added.
The installation followed a grant from the York and North Yorkshire Combined Authority's Mayoral Renewables Fund, which provides cash to the public sector to cut energy bills and reduce emissions.
Listen to highlights from North Yorkshire on BBC Sounds, catch up with the latest episode of Look North.
The owners of the Old York Tea Room say it is not the first time it has been damaged by an HGV.
The plaque was unveiled by Andrew Mountbatten-Windsor at a ceremony in May 2001.
Ravers enjoy a walk and then dance music with their morning coffee before going to work.
City of York Council's Peter Kilbane says investment in culture is needed to combat the far-right.
North Yorkshire Music Therapy Centre is hoping to raise £100,000 to continue their services.
Copyright 2026 BBC. All rights reserved. The BBC is not responsible for the content of external sites. Read about our approach to external linking.
 

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A solar-powered, ultra-light vehicle designed for rural travel has made its public debut in Brittany.
The Scaramobile, a cross between a car and a bicycle, was unveiled in late January along the Boulevard de la Mer in Penvénan, Côtes-d’Armor. 
Its 6.5m² of adjustable solar panels drew immediate attention from passers-by.
Unlike conventional electric cars, the Scaramobile is designed to run largely on its own power, limiting the need for regular charging.
Inventor Denis Baulier developed the project five years ago to fill a gap in rural transport.
“Cities now have many alternative vehicles, but rural areas have been forgotten,” he said. “This vehicle is designed for everyday use, endurance, reliability and carrying capacity, all in a lightweight design.”
Testing in winter was deliberate. “We want it to work from January 1 to December 31,” Mr Baulier said, adding that Brittany’s often cloudy skies would test the solar panels’ efficiency.
The Scaramobile runs on 1,400 watts of solar energy. 
It weighs around 600kg without batteries and can reach 90km/h. Many light vehicles are limited to 45km/h, which discourages drivers from switching from conventional cars. 
Mr Baulier said travelling slightly slower adds less than two minutes to a typical 25km journey. 
The vehicle also breaks traditional design rules. 
There is no steering wheel – instead it is driven by a joystick. 
Pedals do not power the wheels directly but generate electricity for the motor or batteries. Users can choose how much effort to provide, including none at all.
The Scaramobile can carry up to three people or cargo, and its modular bodywork adapts to different uses. 
Mr Baulier also designed it for ease of repair – the modular structure allows components to be replaced over time.
The prototype is the first of three. Mr Baulier said more research is needed, including work with universities. He also pointed to events such as the Bridgestone World Solar Challenge in Australia, a 3,000km solar-powered car race, as a platform for testing innovations.
Pricing is not yet decided. Mr Baulier said it is too early to predict commercial viability, but he hopes the Scaramobile will offer a robust, energy-efficient alternative for rural areas and beyond.
Perhaps surprisingly, the higher-end vehicles are not the most targeted
Vehicles cannot be parked on a public road in the same place for more than seven days
A new law is set to come into force this year
Tests on claimant’s house found high levels of ‘infrasound’ that could not be stopped by home insulation
Undeclared payments cost France up to €7 billion per year, MPs estimate

Confusion over ‘proof of address’ required for request
Some mutuelles include cover for a specific service related to this
Connexion reader argues that criticism of President Macron is unfair
It follows the installation of remotely-read meters to homes around Caen in Calvados. Authorities claim previous readings were incorrect
Image shows red luminous flashes known as ‘sprites’, or farfadets in French
Temperatures set to remain above seasonal highs
New ‘headphone policy’ comes amid expansion of online WiFi services
Romance or a secret? Learn five French expressions related to flowers
Workers in all but essential fields are given May 1 off as a paid holiday

Concrete barriers require less maintenance than metal counterparts and are – arguably – safer
EDF must implement ‘red day’ tariffs before end of month
The number of accounts affected has risen by 79% since 2019
Fuel prices have risen globally but some countries less affected than others
Jet2 to operate from Strasbourg airport for the first time

Updated will was not produced when in sound mind, argues family
Responsibilities include maintenance of communal roads, and civil services such as registering births, marriages and deaths
Speed limits now vary considerably across the country
Country has three-month supply but global instability has caused rush to the pumps
New study shows where it makes more financial sense to buy if living there long term
Department says process has gone well so far but extra staff were recruited to cope with workload
Pit bull terrier Curtis ‘obsessed’ with biting and may have been trained by woman’s partner
Families to lose four years of increased payments. Government will use savings to fund increased parental leave

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Key climate, energy bills fail to advance in legislative session  OregonLive.com
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TAYPRO has introduced a Movable Docking Station that enables solar cleaning robots to move automatically between panel rows, improving utilisation, operational efficiency, and maintenance through integrated sensors, solar-powered charging, and cloud-based monitoring.
March 06, 2026. By EI News Network
TAYPRO has introduced a new Movable Docking Station (MDS) designed to enable autonomous mobility for solar panel cleaning robots, marking a technological advancement aimed at improving operational efficiency in solar power plants across India.

The company said that the battery-powered system allows cleaning robots to move automatically between solar panel rows, reducing manual intervention and improving robot utilisation across multiple arrays.
The MDS transfers solar cleaning robots from one solar panel row to another using precision-aligned railing tracks installed at the ends of panel rows. The docking station moves along these tracks and automatically docks and undocks the cleaning robots. The system is powered by an integrated solar panel-based battery charging mechanism, enabling self-sustaining and energy-efficient operations at solar installations.
According to the company, the docking station is equipped with integrated sensors that align the system precisely with panel rows while ensuring secure locking during robot docking. One of the key advantages of the solution is that it does not require modifications to existing solar panels, allowing quick installation and modular deployment at solar plants.
The system also includes a remote monitoring platform that enables operators to schedule movement and track the position of the docking station. Edge detection sensors prevent derailment and ensure safe operation even in high wind conditions. The railing tracks supporting the system are mounted on columns fixed to the ground using reinforced concrete foundations or ballast systems depending on site conditions.
In addition, the system offers cloud-based maintenance alerts and fault diagnostics to enable scheduled maintenance and minimise unexpected breakdowns, thereby improving the operational life of the equipment.
Commenting on the launch, Yogesh Kudale said that the Movable Docking Station is the result of years of development and technological collaboration. He noted that the system enhances robot utilisation and improves efficiency and performance in solar plants, adding that the solution has already been deployed with one of the company’s clients as part of its initial market rollout.
TAYPRO develops intelligent technologies aimed at improving the performance ratio of renewable energy plants. The company’s solar cleaning robots use patented dual-pass cleaning technology supported by an artificial intelligence framework designed for predictive cleaning, terrain adaptability, battery management and predictive failure detection, helping solar plant operators maximise energy generation and operational efficiency.

Industry is Shifting from Standalone Solar to Integrated Energy Solutions: MD, Truzon Solar

India Must Develop A Robust Testing and Certification Ecosystem for BESS: Ekta Kabra, Geon

Advanced Technology Adoption is Central to Emmvee’s Growth Strategy: Suhas Donthi

Lithium Battery Testing and Semiconductor Labs Infra to Drive Next Phase of Growth: Dibakar Roy

Sunil Wankhede Says Low-Carbon Materials from Alleima India Can Support India’s Climate Goals

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Qcells, a South Korea-based manufacturer of PV cells and modules, has restored solar panel production at its Dalton and Cartersville factories in Georgia. The manufacturing operations had paused temporarily due to a customs clearance interruption affecting imported components required for the facilities’ production processes. According to the company, solar panel output has now returned to normal levels at both Georgia manufacturing facilities. The Cartersville factory began solar module production in April 2025 and is expected to manufacture 3.3 GW of ingots, wafers and cells by 2026. The Dalton manufacturing facility, which opened in 2019, currently produces about 5.1 GW of solar panels annually. Together, the two Georgia factories are expected to employ nearly 4,000 workers and manufacture about 8.4 GW of solar panels annually.

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The proposed Dinawan solar farm in Australia is one of 14 energy projects worth AUD 34 billion ($23.9 billion) endorsed in the first round of the New South Wales state government’s Investment Delivery Authority program.
Image: Spark Renewables
From pv magazine Australia
The proposed Dinawan Solar Farm, developed by Sydney-based Spark Renewables, is among 14 clean-energy and infrastructure projects included in the opening round of endorsements under the New South Wales Investment Delivery Authority’s (IDA) expressions of interest (EOI) process. The endorsed projects together represent about AUD 34 billion in investment.
The Dinawan project is planned for the Riverina region between Jerilderie and Coleambally. It will be located within the South-West Renewable Energy Zone (SW REZ) and form part of the broader Dinawan Energy Hub.
The endorsement does not constitute project approval. Instead, it provides participating projects with specialist government support, including a dedicated concierge service, planning assessment assistance from the Department of Planning, Housing and Infrastructure, and coordination through a multi-agency Investment Taskforce based in the Premier’s Department.
New South Wales Minister for Energy Penny Sharpe said the IDA program is designed to help accelerate delivery of projects under the state’s Electricity Roadmap.
“These endorsed projects will mean more reliable and affordable power for NSW, and more jobs and investment right across the state, particularly in regional NSW,” Sharpe said.
New South Wales Treasurer Daniel Mookhey said the initiative is intended to help unlock major investment by improving coordination across government agencies.
“The projects endorsed represent significant private sector confidence in NSW and the critical role of investment in areas like energy security and the visitor economy,” he said.
The 14 endorsed projects include three battery energy storage systems (BESS), two wind farms paired with batteries, three standalone wind farms, two hydro projects, two energy hubs, and one gas project.
The first IDA EOI round attracted 48 major investment proposals valued at AUD 136 billion. Of these, 22 projects related to renewable energy and energy security worth about $63 billion, while 23 proposals focused on data centers and technology valued at AUD 72 billion.
A New South Wales government statement said insights from the first round show major investment projects are often delayed by system-wide barriers, highlighting the need for a coordinated, whole-of-government approach to unlock investment while managing impacts on energy, the environment and local communities.
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It will be tested in space — This laser gives more energy than 10 solar panels ignited at the same time and even NASA is interested  ecoportal.net
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The benefits of agrivoltaics—the placement of solar panels over cropland for more efficient land use—varies dramatically depending on where it’s located, finds new research from the United States. As agrivoltaics spread and attract more interest, this is one of the first studies to really dig into its inherent trade-offs, and identify places where it works well for both electricity generation and farmers’ bottom lines.
The trade-offs in question are that while the huge increased electricity production enabled by more solar panels is a positive, and renting out land to solar providers can also provide new revenue streams for farmers, the shading effect of solar panels can disturb crop growth. Weighing up these costs and benefits has complicated the picture for farmers who may be considering agrivoltaics on their land.
To shed some light on the issue, a study led by the University of Illinois Urbana-Champaign started by looking at 14 years of maize and soybean crop data from the Midwestern US. The dataset, which included information on crop yield and water-use, compared conventional non-solar cropland with farms where a third of the productive area was covered by panels. They also applied climate simulations to the data, to determine how crop-growing conditions and solar panel impact could change under a low, high, and highest-emission future scenario. 
Very quickly, stark differences appeared in the model, between the more humid eastern stretch of the Midwest, and the drier semiarid western Midwest. 
In the humid east, the shade of the solar panels seemed to reduce photosynthesis levels, dramatically curbing maize yields by 24% and soybean by 16%, compared to conventional no-solar agricultural fields. But in the semiarid west, it was a different picture: maize yields were still reduced by the shading effect, but to a lesser degree of 12%, while there was a win for soybeans, which experienced a 6% increase in yields under panels compared to conventional fields. 
 
 
Previous research has dug into these differences between climate conditions and crops, noting that plants like soybeans are more susceptible to the damaging effects of water loss in hot, dry locations, which affects their yields more than the loss of photosynthesis from shading. In other words, the yield advantages of shading are greater, relative to the disadvantages for soybeans, which may explain some of the differences between crops and locations.
Like yields, the economic picture for farmers is also a mixed bag across the Midwest. In general, the researchers found that the income farmers would generate from leasing land to solar developers was not enough to offset the costs of yield losses: in both the humid east and arid west, for maize farmers total farmer profits decreased by between 6% and 16% respectively on agrivoltaic farms. Soybean farmers had a little more luck: while profits in the humid regions went down by 2%, they increased by 9% in the semiarid parts. 
What’s interesting is that the differences between the two geographical regions and their crops may not be so stark under future climate change. The study’s climate modelling showed that dry regions will expand by between 5.3%, 21.6% and a striking 174% under the low, high, and highest emissions scenarios respectively. With drier, hotter conditions spreading across more of the midwest, “agrivoltaics are likely to become more beneficial” the researchers explain, “offering stronger synergies for sustainable land use.”
For now, agrivoltaics won’t work with a one-size-fits-all approach across the landscape: instead what emerges is a patchwork picture of trade-offs. But the research does at least highlight a starting point, namely some soy cropland hotspots in the arid west, where solar panels could deliver a triple-win—higher yields, economic gains, and clean, green electricity. 
Jia et. al. “Climate-driven divergence in biophysical and economic impacts of agrivoltaics.” PNAS. 2026.  
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By Rachel Cavanaugh
Published Mar 6, 2026 8:10 AM EST
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Choosing the right RV battery setup can make or break your time on the road. Whether you’re boondocking in the desert or topping off your devices at a full-hookup campground, your power source needs to be reliable, efficient, and suited to your style of travel. To find the best options, I researched dozens of batteries and portable power stations, connected with leading brands and experts, and brought a shortlist of finalists on a series of weekend field tests in Oregon.
The products below stood out not just for their specs but for how they performed in real-world scenarios: charging devices, running lights and water pumps, starting the fridge up, and keeping the Starlink powered. From house batteries to portable power stations, here are the best RV batteries of 2026 in every category:
I started by diving deep into spec sheets, online reviews, and expert recommendations, narrowing the field to top contenders across five major categories. Then I hit the road for a weekend field test in Hood River, Oregon, where I was able to test most of them out in person, using my own Lance truck camper to evaluate performance and see if they lived up to the hype.
Testing factors included:
For house batteries, I looked at installation ease, charge cycles, and overall value. For power stations, I tested how well they powered essential appliances and devices, noting each unit’s strengths and trade-offs, as well as things like weight, size, output, and number of ports.
If you want the best of the best for your RV house battery, the Optima Orange Top delivers big time. The lithium iron phosphate battery (LiFePO4) is built for serious off-grid use with enough juice to run demanding appliances or support long boondocking stretches. It’s built with an advanced Battery Management System (BMS) that automatically monitors the battery’s condition and shuts it down if it gets too low. That means you never have to worry about accidentally draining it and causing permanent damage, like with many lead-acid batteries. It also eliminates the need for ongoing maintenance like checking fluid levels and adding water.
Designed with advanced features like Bluetooth connectivity and internal cell heating for cold-weather charging, it’s a smart, rugged choice for year-round adventures. I loved the fold-out dual handles, which made a huge difference when I was lifting and maneuvering the battery into place myself, especially compared to the flimsy single-strap grips on some models that dig into your hands and make heavy lifting awkward. It’s a pricier option, but if you’re going for the absolute best, this battery is definitely worth the splurge.
If you’re looking for a reliable RV house battery at a budget-friendly price point, Renogy’s Deep Cycle AGM is a solid choice. It’s sealed and maintenance-free, so you don’t have to worry about checking water levels or dealing with off-gassing like with traditional flooded lead-acid batteries. It charges reliably in cold temperatures, even below freezing, though it doesn’t have the self-heating feature found in the Optima or other lithium models. It’s also safe to use indoors thanks to its vibration-resistant housing and no-spill design.
That said, this battery doesn’t offer the high-tech features or extended lifespan of a lithium option. It lacks things like Bluetooth monitoring, internal heating, or a battery management system, and recharges more slowly. That said, with durable plate construction and a high discharge rate for short bursts of power, if you don’t need all the bells and whistles it’s one of the most dependable AGM batteries in its class.
While your house battery powers essentials like lights and water pumps, it can be limiting when you’re away from shore power, especially if you need standard outlets, fast charging, or extra capacity outside the rig. That’s where a portable power station like the Ampace Andes 1500 comes in. This unit is a powerhouse among portable options, delivering serious performance while still being compact and lightweight enough to travel with. I got to test this one on the road, taking it out to the desert where I camped in heavy dust, and it held up like a champ. With 2,400W of output and a 1462Wh capacity, it’s strong enough to power everything from laptops to full-size appliances, including most microwaves. The 13 built-in ports (including AC, USB-C, DC, and car outlets) give you tons of flexibility, and it charges lightning fast — juicing up in just 55 minutes via AC (or 3 to 5 hours on solar).
Read Next: Best Portable Power Stations
While several power stations that I looked at incorporated handles for ease of transport, the Anker SOLIX F2000’s were by far the most useful. While the Jackery’s telescoping handle never extended far enough to allow me to stand upright, it was comfortable to pull the Anker SOLIX F2000 by its handle for short distances. This included over very muddy ground during one of my early tests in the summer of 2023. If you regularly move your power stations more than 50 feet at a time, then the ease and comfort with which you can maneuver the Anker SOLIX F2000 makes it a smart choice.
In my test of the best portable power stations, the Anker SOLIX C1000, which uses the same battery chemistry as this model, was a top performer. It was very efficient at delivering large and small amounts of power. Unlike the C1000 model, the Anker Solix F2000 comes with an RV plug built in and a max wattage of 2400 watts (which I did test), equivalent to what a typical RV uses in a day.
The Anker SOLIX 200W Solar Panel was the simplest to use of the larger solar panels I looked at. I liked that it didn’t have a separate carrying case to mess with, and a simple carabiner and mesh bag combo did the trick to stash the relevant cable and ensure it didn’t become separated from the larger unit. Like all of these kickstand solar panel setups, it was a little cumbersome to use, but extra reinforcement on the three kickstand legs were useful, to an extent, when adjusting the panel to a lower angle.
While this solar panel isn’t quite as powerful as the Jackery SolarSaga 200W, it easily produced over 75 percent of its 200-watt capability during my tests — and the Anker SOLIX F2000 can support up to five of these chained together. Strangely, this panel does not have the same sundial component that the Anker SOLIX 100W does. However, after I set up the Anker SOLIX 100W, I adjusted the Anker SOLIX 200W panel to match its angle and immediately saw a 23-watt difference in the power input. Hopefully, Anker will simply add this accessory onto the 200W model in the future, but in the meantime, you can purchase a clip-on sundial separately. 
The Pecron E1000LFP is a great pick if you want the convenience of a portable power station but don’t need to run heavy appliances. It’s not meant for microwaves or A/C units but for charging laptops, running fans, powering Starlink, or topping off devices, it’s a solid, dependable option. I took it on a camping trip in my Lance and loved how lightweight yet rugged it felt. The rectangular shape with smooth, rounded corners made it easier to tuck into corners, and it held up well outside, even in dust and rougher terrain. Despite its smaller size, it still packs 1,800W of output with a 1,024Wh capacity, and features 12 versatile output ports, including USB-C, standard wall-style AC outlets, car ports, and DC ports for flexible charging options. It also has smart features like app and Wi-Fi control, adjustable charging speed, battery temp management, and a built-in UPS. It’s an excellent mid-range pick for weekend adventures, off-grid workdays, or anyone who wants reliable portable power without the bulk. — Laura Lancaster
The Goal Zero Yeti PRO 4000 is the beast of the bunch — a massive, expandable power station designed for serious off-grid setups and crossover home backup. With almost 4,000Wh of capacity and a 3,600W output, this tank can easily handle power-hungry devices like portable A/C units or power tools, making it a reliable choice for extended off-grid stays or backup power on the road. I tested it while camping on a vineyard in Oregon and used it to run an electric grill during an outdoor cookout, and it performed flawlessly: quiet, fume-free, and dependable the whole time. At 115 pounds, it’s not something you’ll casually toss in the back of your camper for a quick weekend, but for more stationary setups or longer trips where serious capacity matters, it shines. It’s a big investment — in both size and price; however, if you’re looking for a high-capacity, self-contained system that pulls double duty for RV and home use, it’s hard to find one better than the Yeti PRO 4000.
When it comes to RV power, there are two primary battery types to choose from: house batteries and portable power stations. They serve different purposes, and in many cases, RVers may want both. Here’s how to shop for each.
Your house battery is the main power source that runs your RV’s built-in systems when you’re not plugged into shore power. This includes things like lights, water pumps, furnace fans, fridges, and other 12V appliances that are wired directly into your rig. Most RVs come with at least one house battery pre-installed, but you may want to upgrade for better performance or longer runtime.
The big decision: Lithium vs. Lead-Acid
What to look for when shopping:
A portable power station is a self-contained battery unit that provides electricity through built-in outlets like standard AC plugs, USB ports, and DC car-style ports. Unlike house batteries, these are external and don’t wire into your RV’s electrical system. They’re perfect for charging laptops, phones, fans, lights, camera gear, and even some small appliances, either inside or outside the rig.
Think of it as a high-powered accessory that gives you more flexibility, especially if you’re camping off-grid or working remotely from your camper.
What to consider when shopping:
Q: What’s the difference between lithium and lead-acid batteries for RVs?
Lithium batteries are lighter, more efficient, and last significantly longer than lead-acid batteries. They can be discharged deeper without damage and recharge much faster but they cost more upfront and require a lithium-compatible charging system. Lead-acid batteries, on the other hand, are heavier and less efficient but more budget-friendly and widely compatible with most factory RV setups.
Q: Can I run my RV off just a portable power station?
Not entirely. A portable power station can handle smaller tasks like charging phones, powering laptops, or running low-wattage appliances, and in some minimalist setups, it may be enough. However, most RVs still require a dedicated 12-volt house battery to power essential systems like lights, water pumps, and propane ignitions. Many travelers use a power station as a supplement — not a replacement — for their RV battery setup.
Q: How long will an RV battery last?
It depends on the type and how you use it. Lithium batteries often last 8 to 10 years or more with 3,000 to 5,000 cycles while lead-acid batteries typically last 3 to 5 years. Runtime on a single charge depends on battery capacity and what you’re powering.
​
After weeks of research and field testing, it became clear that choosing the right RV battery isn’t just about raw specs. It depends on how you camp, where you go, and what your setup requires.
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Box truck carrying solar panels catches fire on I-15 in San Diego  fox5sandiego.com
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The rooftop solar system meets a quarter of the company’s energy requirements
March 6, 2026
Follow Mercom India on WhatsApp for exclusive updates on clean energy news and insights
Solar adoption across India’s commercial and industrial (C&I) segment is growing steadily, with businesses realizing the benefits of reduced power bills and sustainability in their operations.
Grain processing companies with high daytime electricity consumption are increasingly deploying captive solar assets to reduce grid dependence and stabilize long-term electricity costs.
Uttar Pradesh-based Kedarnath Multigrains has commissioned a 659 kW rooftop solar power system at its Shahajahapur facility.
The manufacturing outlet consumes approximately 250,000 units of electricity per month, based on production volumes. The installed solar system generates approximately 65,000 units per month, meeting a significant portion of the facility’s daytime energy requirements.
The company reduced its monthly electricity bills from ₹1.6 million (~$17,440) to ₹1.8 million (~$19,620) to around ₹400,000 (~$4,360) to ₹500,000 (~$5,450), depending on production cycles and seasonal factors. The reduction has been achieved through lower grid drawal during peak sunlight hours and net billing adjustments.
Kedarnath Multigrains operates grain processing, milling machinery, storage infrastructure, and auxiliary systems that require continuous and large amounts of electricity.
Shashwat Agarwal, Director at Kedarnath Multigrains, said the decision to install the rooftop solar system was driven by cost management and operational efficiency. “Solar has helped us reduce grid dependency and bring down monthly power expenses.”
The project was executed by Grun Power, which deployed high-efficiency TOPCon bifacial solar photovoltaic modules to enhance output and long-term performance.
Ashish Tak, Co-founder at Grun Power, said the technology selection was focused on maximizing generation within the available rooftop footprint. “We designed the 659 kW system to deliver higher energy output and stable performance. The execution was completed without major challenges.”
In addition to cost savings, Kedarnath Multigrains cited environmental considerations as a key factor behind the investment. The company stated that solar power supports its goal of reducing pollution and operating more sustainably.
Grun Power provides post-installation services, including system monitoring, routine maintenance, performance analysis, and technical support to ensure long-term efficiency.
Based on the current installation’s performance, Kedarnath Multigrains is considering expanding the facility’s solar capacity and exploring similar installations at its other units.
Mercom India hosts a pan-India ‘C&I Clean Energy Meet’ series, bringing renewable energy developers and commercial and industrial power consumers together to discuss the options available for adopting renewable energy.
The next event will be held in Bhopal on March 13, 2026.
Meghana Prasad
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The global concentrated solar power market is expected to witness high growth potential in coming years due to a surge in demand for renewable energy and favorable government incentives, subsidies, and policies.
According to a new report published by Allied Market Research, the Concentrated Solar Power Market size was valued at $6.1 billion in 2022 and is projected to reach $28.2 billion by 2032, registering a CAGR of 16.6% from 2023 to 2032. The rapid shift toward clean energy solutions, supportive government policies, and increasing investments in renewable power infrastructure are key factors driving the expansion of the Concentrated Solar Power Market worldwide.

Understanding Concentrated Solar Power Technology

Concentrated Solar Power (CSP) is an advanced renewable energy technology that generates electricity by using mirrors or lenses to concentrate sunlight onto a small area. This concentrated sunlight produces heat, which is then used to generate steam that drives a conventional turbine or engine to produce electricity.

Various technologies are used in CSP systems, including parabolic troughs, solar power towers, dish/engine systems, and linear Fresnel reflectors. These technologies concentrate solar radiation to produce high temperatures, enabling efficient electricity generation.

One of the key advantages of CSP systems is the integration of thermal energy storage. Unlike other solar technologies that depend entirely on sunlight, CSP plants can store heat and generate electricity even when sunlight is unavailable. This capability significantly enhances grid reliability and strengthens the growth potential of the Concentrated Solar Power Market.

By Region

Regionally, the market is analyzed across North America, Europe, Asia-Pacific, and LAMEA. Asia-Pacific accounted for the largest revenue share in 2022 and is projected to witness the fastest growth during the forecast period.

Rapid industrialization, rising electricity demand, and growing awareness of climate change are encouraging governments across the region to invest heavily in renewable energy technologies. CSP’s low carbon footprint and minimal environmental impact make it an attractive solution for countries aiming to reduce greenhouse gas emissions.

Government Support Driving Market Growth

Government support plays a crucial role in accelerating the adoption of CSP technology across the globe. Many governments provide financial incentives such as grants, subsidies, tax credits, and low-interest loans to encourage the development of large-scale solar power plants.

These incentives help offset the high initial investment required for building CSP facilities. Additionally, governments are simplifying regulatory procedures, including permitting processes and grid interconnection guidelines, to facilitate project development.

Government-funded research and development initiatives are also contributing to technological advancements in CSP systems. Continuous innovation aimed at improving efficiency, reducing costs, and enhancing energy storage capabilities is further supporting the growth of the Concentrated Solar Power Market.

High Installation Costs Remain a Key Challenge

Despite its advantages, the Concentrated Solar Power Market faces certain challenges that could limit its growth. One of the major constraints is the high upfront cost associated with constructing CSP plants.

CSP systems involve complex technologies such as parabolic trough collectors, solar power towers, or dish engines. The installation of specialized components including mirrors, receivers, heat transfer fluids, and thermal storage systems significantly increases the initial capital expenditure compared to other renewable energy technologies.

Another challenge is the requirement for large land areas. CSP plants need extensive land to install solar collectors and related infrastructure. In regions with high direct sunlight—where CSP plants are most effective—land prices are often high, further increasing project costs.

These factors can slow down investments in new CSP facilities and pose challenges for the Concentrated Solar Power Market, particularly in regions with limited land availability or financial constraints.

Hybrid Renewable Systems Creating New Opportunities

The integration of CSP with other renewable energy technologies is creating promising opportunities for the Concentrated Solar Power Market. Hybrid power plants that combine CSP with photovoltaic solar panels or wind energy systems are gaining popularity in the global energy sector.

By combining multiple renewable technologies, hybrid plants can overcome the limitations of individual power sources. For instance, CSP systems can provide thermal storage and stable electricity output, while photovoltaic panels can generate power during peak sunlight hours.

Such hybrid systems help stabilize power supply, reduce energy fluctuations, and improve grid reliability. The growing demand for integrated renewable power solutions is expected to create significant growth opportunities for the Concentrated Solar Power Market in the coming years.

Impact of Economic Uncertainty on Market Growth

Economic downturns and financial crises can have a considerable impact on investments in renewable energy projects, including CSP infrastructure. During periods of economic uncertainty, investors and project developers often delay large-scale energy investments due to financial risks.

The high initial capital required for CSP projects can make them less attractive during economic slowdowns. Businesses and governments may prioritize cost-saving measures and postpone new renewable energy projects until financial conditions stabilize.

However, economic challenges can also stimulate competition in the energy sector. Increased competition often encourages companies to innovate and improve efficiency while reducing production costs. As a result, economic pressures can drive technological advancements and long-term improvements in CSP technology, strengthening the resilience of the Concentrated Solar Power Market.

Market Segmentation Overview

The Concentrated Solar Power Market is segmented based on technology, end-use industry, and region.

By Technology
The market includes parabolic trough systems, solar power towers, Fresnel reflectors, and dish Stirling systems. Among these technologies, the solar power tower segment accounted for the largest revenue share in 2022.

Meanwhile, the Fresnel reflector segment is projected to grow at the fastest rate during the forecast period, with an expected CAGR of 17.6%. These systems are gaining popularity due to their simpler design and lower installation costs.

By End-Use Industry
Based on end-use industry, the market is classified into residential, commercial, and industrial sectors. The industrial segment generated the highest revenue share in 2022, as industries increasingly adopt renewable energy solutions to reduce operational costs and carbon emissions.

However, the residential segment is expected to experience rapid growth, with a projected CAGR of 17.1%. Residential CSP systems can provide homeowners with greater energy independence by reducing reliance on centralized power grids and fossil fuels.

Competitive Landscape

Major companies operating in the Concentrated Solar Power Market include Aalborg CSP, Acciona, ACWA Power, Atlantica Sustainable Infrastructure plc, BrightSource Energy, FRENELL GmbH, General Electric, Rioglass Solar, Sener, and Siemens Energy AG.

Other notable companies contributing to market development include Abengoa Solar, SolarReserve, TSK Flagsol Engineering GmbH, Schott AG, Cobra Group, Novatec Biosol, and Enel Green Power.
These companies are focusing on strategic partnerships, technology innovations, and project expansions to strengthen their market position globally.

Conclusion

The Concentrated Solar Power Market is poised for significant growth over the next decade as countries accelerate their transition toward sustainable energy systems. Increasing investments in renewable energy infrastructure, supportive government policies, and technological advancements in thermal storage are expected to strengthen the adoption of CSP technology. Although high installation costs remain a challenge, innovations and hybrid renewable energy systems are likely to unlock new growth opportunities for the global market.

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Cartersville’s 3.3 GW of solar module production began in April 2024, adding to its impressive output of 5.1 GW from its Dalton, Georgia location, which opened in 2019. By the end of the year, these two facilities will have a combined workforce of nearly 4,000 people building 8.4 GW of solar panels and their key components each year.
DALTON, Ga., CARTERSVILLE, Ga.– Today, Qcells announced its solar panel output being back to normal production after its temporary pause due to a customs clearance process. Meanwhile, its Cartersville, Georgia factory is expected to have the capacity to manufacture 3.3 GW of ingots, wafers, and cells by the end of 2026.

Cartersville’s 3.3 GW of solar module production began in April 2024, adding to its impressive output of 5.1 GW from its Dalton, Georgia location, which opened in 2019. By the end of the year, these two facilities will have a combined workforce of nearly 4,000 people building 8.4 GW of solar panels and their key components each year.

Marta Stoepker, Head of Communications at Qcells, issued the following statement:

“We are proud to be back to work manufacturing the American-made energy the country needs right now. Like any company, hurdles have and will occur, which requires us to adapt and be nimble, but our overall goal remains the same — to build a complete American solar supply chain.

“To achieve this, we are excited to welcome hundreds of new, talented people into our workforce as we finalize our one-of-a-kind factory in Cartersville, Georgia. By the end of 2026, we’ll have nearly 4,000 people manufacturing panels and components that America hasn’t made in a very long time.”

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About Qcells

Qcells is one of the world’s leading clean energy companies, recognized for its established reputation as a manufacturer of high-performance, high-quality solar cells and modules, portfolio of intelligent storage systems, and growing international pipeline of large-scale renewable energy projects. Qcells also provides renewable electricity retail services and packages to end customers across the world. The company is headquartered in Seoul, South Korea (Global Executive HQ) with its diverse international manufacturing facilities in the U.S., Malaysia, and South Korea. Qcells offers Completely Clean Energy through the full spectrum of photovoltaic products, storage solutions, renewable electricity contracting and large-scale solar power plants. Through its growing global business network spanning Europe, North America, Asia, South America, Africa and the Middle East, Qcells provides excellent services and long-term partnerships to its customers in the utility, commercial, governmental and residential markets. For more information, visit: https://qcells.com/us.

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