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India maintained that its measures were entirely consistent with WTO law
May 28, 2026
Follow Mercom India on WhatsApp for exclusive updates on clean energy news and insights
India recently rejected a request from China to set up a dispute panel at the World Trade Organization (WTO) to investigate India’s tariffs on imported high-tech goods and incentives for solar energy products.
China wanted a dispute panel to determine whether import tariffs and incentive measures for solar energy products that it says are contingent on the use of domestic rather than imported goods are consistent with India’s WTO commitments.
China said consultations were held with India for a mutually satisfactory solution, but they failed to resolve the dispute, prompting China’s request for the panel.
It said members should promote their technological and industrial development through cooperation consistent with WTO rules, rather than through restrictive and discriminatory measures that undermine competitive opportunities, disrupt supply chains, increase uncertainty for businesses and operators, and adversely affect the healthy development of global renewable energy and technology sectors.
In response, India rejected China’s demand for a panel. It noted that it had engaged in extensive talks with a view to reaching a mutually satisfactory resolution. India said it was surprised China had not undertaken an actual consideration of the measures at issue, adding that it believes the measures in question are entirely consistent with WTO law.
It was strange that, despite the importance of a responsible and diversified supply chain, a country estimated to control more than 80% of the global value chain for solar module production felt it necessary to take action to stymie the legitimate growth of this industry in other countries.
The WTO’s Dispute Settlement Body agreed to consider the matter if it was brought up again.
Last December, China had complained to the WTO against India’s solar photovoltaic subsidies, alleging that they provide an unfair competitive advantage to Indian companies and harm Chinese interests.
Two months earlier, the country had also filed a complaint over India’s subsidies for electric vehicles and battery manufacturing.
Parth Shukla
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© 2026 by Mercom Capital Group, LLC. All Rights Reserved.

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Sunkind India is entering the solar module manufacturing sector with a major solar cell procurement agreement valued between ₹1,200 crore and ₹1,500 crore. The move marks a significant milestone in the company’s expansion strategy as it strengthens its presence in India’s rapidly growing renewable energy and solar manufacturing ecosystem.
Company Sets Up 1 GW Solar Module Manufacturing Facility
As part of its expansion plans, Sunkind India has established a 1 GW solar module manufacturing line near Jaipur, Rajasthan. The company expects to begin commercial production next month after successfully completing trial operations at the facility. The manufacturing unit is expected to support the company’s long-term growth ambitions while improving operational efficiency across its renewable energy business.
Strategic Procurement Deal to Support Manufacturing Operations
To support the manufacturing vertical, Sunkind India has signed an agreement with a domestic solar cell manufacturer for the procurement of 1 GW of DCR (Domestic Content Requirement) solar cells. According to Managing Director Hanish Gupta, the procurement agreement will play a critical role in ensuring a stable supply chain for the company’s upcoming solar module production operations. The order value is estimated between ₹1,200 crore and ₹1,500 crore, highlighting the scale of the company’s manufacturing ambitions.
In-House Manufacturing to Improve Project Execution
Currently, Sunkind India operates primarily in the solar EPC (engineering, procurement and construction) and independent power producer (IPP) segments, with a strong focus on commercial and industrial solar projects. By entering module manufacturing, the company aims to improve project execution timelines, strengthen supply chain integration and enhance overall operational control. The strategy is also expected to reduce dependence on external suppliers while helping the company better manage project costs and delivery schedules.
India’s Solar Manufacturing Sector Continues to Expand
Sunkind India’s latest investment reflects the broader momentum in India’s domestic solar manufacturing industry, driven by government initiatives promoting local production and renewable energy self-reliance. As demand for domestically manufactured solar components continues rising under India’s clean energy transition plans, companies across the sector are increasingly investing in integrated solar manufacturing capabilities. As reported by projectstoday.ai, with the launch of its manufacturing operations, Sunkind India is positioning itself to participate more actively in India’s expanding solar value chain and renewable energy growth story.

1,true,6,Contact Email,21,false,1,First Name,21,false,1,Last Name,2


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From pv magazine Australia
The installation of almost 500,000 solar panels at the France-headquartered developer ENGIES‘s Goorambat East Solar Farm in Victoria will be completed by October 3, thanks in part to a collaboration with US robotics company Luminous, which has trialled its first LUMI S4 fleet during construction.
ENGIE Site Representative Justin Webb said commissioning has commenced, and first energization of the Goorambat East Solar Farm is expected by end of October 2025, with full operations on target for mid-2026.
“It will have a generating capacity of up to 250 MW, which is enough to power up to 105,000 average Victorian homes,” Webb said.

Located near Benalla, 210 km northeast of Melbourne, the demonstration of the AI-powered LUMI pick and place robot at Goorambat addresses the industry’s most labor-intensive task of panel installation.
LUMI autonomously places solar modules onto racking structures, allowing onsite workers to complete the final securing process, reducing manual labour and improving installation speed, safety and cost-efficiency.
“The system was used to install pilings and more recently solar panels, with American company Luminous testing their LUMI system outside of the US for the first time and demonstrating the future of solar farm construction,” Webb said. “The intended higher productivity of these autonomous systems will reduce the cost of renewable energy projects and enable projects to be built in less time – which will bring down energy costs for consumers and potentially allow more solar farms to be built.”
The robots also require skilled technicians to operate them, resulting in upskilling the current renewable energy workforce and enabling more productivity, Webb added.
“The use of autonomous robots could also have large benefits for the construction of solar farms in remote and inhospitable areas, such as is deserts, where the climate could be dangerous for human staff.”
“In the longer term, with continued development, robots like these will also enable a reduction in health and safety related risks from construction projects, for example reducing the manual handling of heavy solar panels.”

Luminous Robotics Inc. Chief Executive Officer and Founder Jay M. Wong said deploying the company’s LUMI fleet in Australia allowed it to capture the data, performance insights and real-world impact needed to drive global adoption.
“Our LUMI robots exceeded our target production rate and fueled by support from the Australian Renewable Energy Agency (ARENA), we’re keen to accelerate our next phase where we fine tune the LUMI fleet’s capabilities,” Wong said.
“This will further advance and optimize flow, autonomy, reliability, manufacturability, and massively improve the construction of energy infrastructure at scale.”
Wong said in the coming months Luminous and ARENA will release and open source solar construction’s largest, most comprehensive robotics dataset.
“We believe this is the honest approach to truly democratize solar for humanity. Such that this effort becomes the fuel on which innovative solutions, not just for panel installation and construction, but the holistic, collective industry can benefit from, in accelerating the planet into a future of true solar scale up.”

Project partner France-headquartered Bouygues Construction Australia Project Director Bastien Sauvet said with support from ARENA and its joint venture with Sydney-based Equans Solar and Storage Australia, this first deployment outside the US showcases how robotics can improve safety, quality and productivity in solar farm construction.
“It is a promising step, and it will be exciting to see how robotics can help shape the future of renewable energy in Australia, Sauvet said.
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Top Stories Of The Day: Evolve Green Secures ₹1 Billion Funding; Sunkind India Locks 1 GW Solar Cell Supply; SolarEdge Opens New Bangalore R&D Campus and More…  SolarQuarter
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Insolation Energy Plans Cell Production By Q3/Q4, Sees It As Major Profitability Driver Photograph: (AI)
Insolation Energy expects to commence production from its upcoming 4.5 GW solar cell manufacturing facility by Q3/Q4 FY27, with the company identifying the project as its biggest long-term profitability driver as India transitions towards deeper domestic solar manufacturing under stricter localisation norms.
Speaking during the company’s Q4 FY26 investors call, management said the Narmadapuram-based solar cell plant in Madhya Pradesh is progressing as planned and will significantly improve margins, strengthen backward integration and enhance competitiveness under the evolving ALMM framework.
“Our EBITDA margin should increase whenever the cell line becomes operational,” the company said during the call, adding that margins could expand from the current 14-15% range to 17-18% initially and eventually cross 20% once the entire facility stabilises at optimal utilisation.
The company expects phased commissioning to begin in Q3/Q4 FY27, with full ramp-up likely by Q1 FY28. Insolation said the entire 4.5 GW capacity may not become operational immediately, but production will progressively scale over the subsequent quarters.
The solar cell facility forms the centrepiece of Insolation Energy’s broader strategy to transform itself from a module manufacturer into a fully integrated solar manufacturing company. Alongside the cell project, the company is also expanding aluminium frame manufacturing capacity and preparing future plans for wafer and ingot manufacturing.
Management indicated that backward integration has become increasingly critical amid the government’s implementation of Approved List of Models and Manufacturers (ALMM) and domestic content requirement (DCR) policies, which are expected to sharply increase demand for locally manufactured solar cells.
The company sounded particularly bullish on the domestic solar cell opportunity, noting that India still faces a sizeable gap between solar module manufacturing capacity and domestic cell availability.
“Lots of India market is now available for solar cell supply also,” management said during the interaction, highlighting that several projects awarded before tighter localisation norms still permit non-DCR modules, creating additional transitional demand over the next 12-18 months.
To support the expansion, Insolation Energy has earmarked nearly Rs 1,500 crore capex for the solar cell facility, while total FY27 capex guidance stands at around Rs 2,500 crore including investments in IPP and PM-KUSUM-linked renewable energy projects.
The company acknowledged that debt levels would rise sharply during the expansion phase, with peak debt expected to approach Rs 1,500 crore during FY27. However, management argued that the integrated manufacturing model would eventually generate strong operating cash flows once the cell facility reaches stable utilisation.
Insolation Energy currently operates 5.5 GW of solar module manufacturing capacity and is targeting module sales of 2-2.5 GW during FY27. Management maintained that revenue growth momentum similar to FY26’s 60%-plus expansion could continue in FY27 depending on market conditions and the impact of ALMM implementation from June 2026 onward.
The company also revealed that it has already secured additional land in Madhya Pradesh for future wafer and ingot manufacturing projects and aims to establish upstream manufacturing before ALMM Part-III comes into force in June 2028.
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NJBIZ Leaders in Real Estate, Construction and Design

Jessica Perry//May 27, 2026//
An aerial overview of the AvalonBay Boonton property showing rooftop solar arrays, installed by PowerLutions Solar, across the multifamily community. – PROVIDED BY POWERLUTIONS
AvalonBay adds rooftop solar at Boonton apartments
An aerial overview of the AvalonBay Boonton property showing rooftop solar arrays, installed by PowerLutions Solar, across the multifamily community. – PROVIDED BY POWERLUTIONS

Jessica Perry//May 27, 2026//
Things are looking bright in Boonton, where PowerLutions Solar completed a multi-interconnection rooftop solar project atop an AvalonBay apartment property in Morris County.
According to the May 26 announcement, the 747 kilowatt DC system generated approximately 821 megawatt hours in its first year. The installation is expected to deter about 300 metric tons of carbon dioxide emissions annually — enough to power more than 40 homes for one year.
PowerLutions said the effort is designed to offset a significant share of common-area electricity use at the property. It developed and delivered the project with REV Energy Ventures along with Avalon Bay Communities Inc.

At the Boonton multifamily development, 13 interconnections run across multiple rooftops. The work uses Talesun modules, PowerLutions said, and Enphase microinverters. These efforts support module-level performance, safety and reliability, according to the Lakewood-based company.

The system is interconnected with JCP&L under the state net-metering framework. It is also positioned to participate in applicable state solar incentive programs.

Clean-energy commitment

Noted PowerLutions Solar Vice President Cy Yablonsky, “Through detailed load mapping and staged commissioning, we completed a resident-first solar upgrade and helped avoid a costly transformer upgrade.”

“AvalonBay’s sustainability platform combines smart development, efficient operations, and innovative strategies to reduce environmental impact across our growing portfolio,” said that company’s vice president of sustainability, Gautami Palanki. “Our emissions targets, clean energy investments, and partnerships with companies like PowerLutions Solar reflect our commitment to delivering resilient, high-performing communities.”
The partners noted the work creates value for the property, as well as the surrounding community.

According to the Solar Energy Industries Association and New Jersey installation data, New Jersey ranks 13th nationwide for total cumulative installed solar PV capacity and second in solar per square mile (after Rhode Island) as of late 2025, according to the state Department of Environmental Protection.

“This project reflects how strategic clean energy partnerships can help real estate owners advance their sustainability goals while delivering meaningful long-term energy savings,” said Jeff Bedard, managing partner at Colorado-based solar designer REV Energy Ventures.
Avalon Boonton offers studio, one-, two- and three-bedroom apartments featuring modern finishes and thoughtful design. Beyond the new solar setup, amenities include a fitness center, outdoor pool, resident lounge and more. The community offers convenience to surrounding Morris County townships, such as Morristown or Florham Park. It sits a half mile from the NJ Transit Montclair-Boonton Line, and in close proximity to Interstates 287 and 80.

AvalonBay and Equity Residential revealed plans to merge in an all-stock deal May 21. The deal aims to “expand margins, accelerate growth, and redefine leadership in rental housing,” according to the announcement. The new company will have a pro forma equity market capitalization of approximately $52 billion and a total enterprise value of approximately $69 billion. It would include more than 180,000 rental apartments.
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India’s solar industry is expanding at a pace unmatched in global clean energy. EUPD Research estimates that the country will install 213 GW of new solar capacity between 2025 and 2029, averaging 42 GW a year. Yet manufacturing capacity is rising far faster, creating a structural surplus that could redefine global supply and pricing.
By 2030, India’s module manufacturing capacity is projected to exceed 280 GW, with cell capacity jumping from 26 GW in 2025 to 171 GW, a 6.6-fold increase. Wafer production could reach 45 GW, indicating deeper upstream integration. This growth is underpinned by policies such as the Production-Linked Incentive (PLI) scheme, Domestic Content Requirement (DCR) mandates, and Approved List of Models and Manufacturers (ALMM-I and ALMM-II), which are designed to localize supply chains and reduce import dependence.
However, domestic demand cannot absorb this expansion. According to EUPD Research’s latest report titled India’s Solar Surge: The Next Looming PV Price Shock?, even at 65% capacity utilization factor (CUF), India’s export potential could reach 143 GW by 2030, while the annual average domestic demand remains around 42 GWdc. This annual manufacturing capacity would be enough to cover the forecasted demands of India, North America and the EU-27 combined!
The country is transitioning from self-sufficiency toward export dependence, with the U.S. market accounting for nearly 97% of shipments in 2024 (4.3 GW). However, with 50% tariffs now in effect, the U.S. market has tightened significantly for Indian manufacturers, with just 1.86 GW of module imports in the first half of 2025. Therefore, to maintain utilization and margins, Indian producers must expand into Europe, where diversification policies and sustainability standards are shaping future demand, and also into the Middle East, Africa, and other emerging markets.
Export Potential: Sensitivity Analysis Across Varying Capacity Utilizations

Source: EUPD Research 2025
Price Parity in Sight: India Begins to Bridge the Price Divide with China
India’s surge is about both capacity and competitiveness. The spot price gap between Indian and Chinese TOPCon modules has narrowed, from 9 to 5.7 US¢/W between Q1 2024 and October 2025. This convergence suggests India is steadily narrowing the price gap with Chinese manufacturers.
Even so, production costs remain higher. India’s average minimum sustainable price is 17% above China’s and 14% above Southeast Asia’s (SEA), reflecting smaller scale and limited integration. Falling upstream component prices and new production lines are helping narrow the gap, but competitiveness still varies by market. In the U.S., following the introduction of 50% tariffs on India-made goods, the price gap between Indian and SEA modules has doubled, rising from 3.1 to 6.2 US¢/W, impacting the competitiveness of Indian modules.
In the domestic market, India-made modules remain about 40% costlier than Chinese ones, a cost difference largely driven by the DCR premium enjoyed by local producers. This premium, alongside the 20% basic customs duty and ALMM mandate, effectively protects the home market, allowing domestic manufacturers to maintain elevated prices.
Beyond Price: Carbon, Freight, and ESG Edges
As PV markets mature, competitiveness increasingly depends on non-price factors such as carbon footprint, logistics, and ESG performance. These elements could become decisive for Indian manufacturers seeking to expand in Europe and other regulated regions.
As per EUPD Research calculations, freight costs from India to Europe account for about 5% of module price, compared with 8.7% from China, giving India a logistics advantage. The carbon emission intensity of Indian freight is roughly 65% lower than that of Chinese shipments to Europe, due to shorter routes. These attributes align strongly with Europe’s Carbon Border Adjustment Mechanism (CBAM) and Net-Zero Industry Act (NZIA), which prioritize low-carbon, traceable imports.
Currently, Indian manufactured modules are less carbon-intensive than Chinese equivalents. Yet Chinese producers are closing the gap by greening their manufacturing. Indian firms, meanwhile, have to address efficiency shortfalls: domestic TOPCon modules are 1–1.5 percentage points less efficient than leading global brands. Chinese manufacturers also lead in R&D advancement and patent activity, with the majority of global solar technology patents originating from Tier-1 Chinese firms. For Indian manufacturers, strengthening research capabilities and innovation focus will be essential to gain a competitive, non-pricing edge in global markets.
On ESG transparency compliance, Chinese Tier-1 firms still lead in the regulatory landscape, environmental standards and other parameters, courtesy of their scale, global experience, and established systems, according to EUPD Research analysis of the Tier-1 Chinese and the Indian module manufacturers. For Indian exporters, bridging this gap is crucial. As Europe enforces stricter sustainability and human-rights rules, transparent reporting and supply-chain traceability is key for successfully supplying  ESG-sensitive large commercial, industrial and utility segments.
Comparative ESG Performance: Top Indian and Chinese Manufacturers

Source: EUPD Research 2025
With carbon, freight, and ESG metrics becoming new trade filters, Indian manufacturers have an opening to position themselves as low-carbon, credible alternatives to Chinese suppliers, provided they act quickly to align with evolving European standards.
Global Fallout: Overcapacity, Trade Shifts, and New Power Balances
India’s rapid capacity buildup will have wide global implications. With India’s module manufacturing capacity likely exceeding 280 GW by 2030, the world could face a new wave of PV oversupply that drives module prices lower. This parallels earlier phases of Chinese module manufacturing expansion, though with a new competitive geography emerging in Asia.
For China, India’s rise introduces margin pressure in mainstream segments. As price parity approaches, Chinese firms are expected to pivot toward high-efficiency and next-generation technologies such as high-efficiency n-type TOPCon, heterojunction (HJT) and perovskite tandem modules. China’s global market share is expected to decline over the coming years as diversification efforts progress, assuming continued expansion into new regions and technology segments.
In Europe, the outlook is mixed. Persistent price softness could make Asian imports 25–30% cheaper than European-made modules, undermining on-shoring efforts even with subsidies. Yet this same environment opens the door for Indian suppliers that comply with CBAM and NZIA rules. Europe’s demand, exceeding 65 GW annually, combined with its focus on sustainability and supply-chain resilience, could make it India’s next major growth market. Joint ventures, licensing partnerships, and traceability-linked co-production models between Indian and European manufacturers are likely to increase.
For India, overcapacity is both an opportunity and a challenge. Large, integrated players may consolidate market share, while smaller firms face margin stress. India’s position as a diversification hub in global clean-tech supply chains will strengthen if it can align with trade frameworks such as the India–EU Free Trade Agreement (FTA).
The deal under negotiation would align testing and certification standards, reduce duplicate compliance costs, and encourage collaboration on sustainability and labour norms. Once finalized, the FTA could grant Indian manufacturers easier market entry, lower non-tariff barriers, and better positioning if Europe later imposes carbon-based trade restrictions on high-emission imports.
Moreover, several European buyers and intermediaries have been diversifying their procurement toward alternative suppliers as part of broader risk-mitigation strategies, as seen with earlier shifts toward Chinese manufacturers, according to EUPD Research’s PV InstallerMonitor© | EES InstallerMonitor© findings. This evolving sourcing landscape creates a timely opportunity for Indian manufacturers to expand their market share in Europe.
Conclusion
India’s solar manufacturing boom marks a turning point in the global PV industry. Rapid capacity growth, narrowing cost gaps with China, and lower carbon intensity are propelling India into an export-driven phase. Yet these same trends risk creating oversupply and price compression if diversification does not keep pace.
With major markets like China, the United States and Europe showing signs of slowdown, including project delays, financing constraints, and weaker installation margins, global price pressures are likely to intensify. While top Indian manufacturers remain financially stable for now, sustaining capacity utilization will depend on expanding into new markets and aligning early with low-carbon, compliant trade regimes.
To stay competitive, Indian manufacturers must act quickly. Europe offers a critical opening as it seeks reliable, low-carbon suppliers under the CBAM and NZIA frameworks. Early alignment with these standards will be key to securing long-term positions in premium markets.
Sustained competitiveness will depend not only on scale, but on speed, focus, and differentiation. As global competitive intensity rises, time to market and disciplined execution are becoming decisive differentiators. The race for market share is increasingly costly, and chasing volume without clear value creation or profitability risks becoming a trap. The key question is no longer who can produce the cheapest module, but who can identify the right markets, define the right segments within the identified markets contributing over average to net profitability, and move first with the right offering.
To thrive in this environment, Indian manufacturers must evolve beyond production scale and embrace data-driven market evolution. This means understanding how to tier markets, segment customers, and position premium products that deliver measurable differentiation. The ability to match technology and pricing strategy with the most receptive demand pockets will define who captures tomorrow’s opportunities.
This is precisely where EUPD Research provides its decisive value. For more than 25 years, EUPD has been delivering impactful, data-backed solutions that enable manufacturers to understand markets, identify high-potential segments, and connect with the right stakeholders. Through its unique approach, combining intelligent market tierisation, stakeholder access, and impactful communication, EUPD transforms complexity into clarity and data into direction. Its frameworks empower companies to detect emerging trends early, choose the right strategic moves, and accelerate their time to market with confidence.
If managed effectively, India’s solar surge can consolidate its position as a cornerstone of clean-tech diversification. But to achieve this, manufacturers must act now, pairing scale with strategic foresight, market intelligence, and trusted expertise. Those who leverage data sovereignty, digitalization and market intelligence to understand where to play, how to win, and how to differentiate will not just win the race; they will win the market itself, securing enduring strength and premium positioning for the decade ahead.
Ultimately, sustainable leadership will belong not to those who invest the most in production, but to those who quickly balance technological excellence with data-driven intelligence and precise market execution.
About the Authors:
Markus A.W. Hoehner is the Founder, President and Chief Executive Officer of Hoehner Research & Consulting Group and EUPD Group. He has been active in top-level research and consulting, focusing on cleantech, renewable energy, and sustainable management for more than three decades. He can be reached at [email protected].
Rajan Kalsotra is a Senior Consultant at EUPD Research, bringing over 14 years of experience in the renewable energy sector. His expertise encompasses market research, policy development, and strategic consulting. He has collaborated with leading energy organizations, delivering valuable insights into the global renewable energy landscape, with a particular focus on solar energy, energy storage, and emerging technologies. He can be reached at [email protected].
Abhinandan Khajuria is a Renewable Energy Analyst at EUPD Research, focusing on analyzing global solar PV and battery markets, understanding international policies, engaging stakeholders, and undertaking research to deliver valuable inputs for the clean energy market. He can be reached at [email protected].
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Wednesday, June 3, 2026
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Wednesday, June 10, 2026
3:00 pm – 4:00 pm CEST, Berlin, Paris, Madrid
Tuesday, June 9, 2026
11:00 am – 12:00 pm CEST, Berlin, Paris, Madrid
Thursday, June 11, 2026
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Monday, June 1, 2026
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Tuesday, June 16, 2026
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The new pv magazine Global May issue is now available!
Mountains to climb
Available in print and digital formats.
Be part of the high-level European conference on solar and energy storage, exploring bankable BESS projects, warranties, and energy management for residential and C&I sectors
Entries open in seven categories: Modules, Inverters, BoS, BESS, Manufacturing, Sustainability, Projects.
April 01 – August 31, 2026
A two-day conference in Austin, Texas, bringing together leaders in US solar manufacturing, equipment specification, and factory execution.
Saudi Arabia is accelerating its clean energy transition—join the SunRise Arabia Clean Energy Conference 2026 in Riyadh to explore how solar PV and energy storage are powering its digital economy.
Showcase your brand across all our platforms: from 13 websites in 7 languages to our magazines, daily newsletters, industry events and more. Reach your audience the right way!
We are participating in Intersolar 2026 again this year! Visit us at our Booth Hall 2 A2.250 to discuss the latest trends within the photovoltaic industry with the pv magazine team.
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Sweden-based steelmaker SSAB has announced that it has delivered decarbonized steel for a solar park project being developed in Germany by Swedish power company Vattenfall, highlighting growing demand for lower-emission steel products in renewable energy infrastructure.
SSAB Zero™ will be used in the supporting structures on which the solar panels are mounted. In total, more than 9,000 steel profiles will be used, with a combined weight of 209 tonnes. 
The project forms part of broader efforts across Europe to reduce embedded carbon emissions in energy and construction supply chains.
Decarbonized steel used in solar infrastructure
According to SSAB, the steel supplied for the project was produced using the company’s low-emission steelmaking technologies aimed at significantly reducing carbon emissions compared to conventional blast furnace production.
The material is being used in structures connected to Vattenfall’s solar park development in Germany, where sustainability and lifecycle emissions reduction are increasingly important procurement criteria.
“The electricity generated from this solar farm will help reduce Germany’s dependence on imported fossil fuels. But for us fossil freedom does not end with electricity generation – it starts right at the beginning of the supply chain. That is why we are pleased to take this pioneering step together with our partner SSAB, using low emission steel for the substructures. By leading the way as a company, we support the long-term societal goal of becoming fossil free,” Claus Wattendrup, head of Solar and Batteries at Vattenfall, said.
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Global solar PV deployment is entering a phase of adjustment. After several years of rapid expansion, installation growth is stabilizing across multiple major markets. EUPD Research calculations suggest that global additions in 2026 may not exceed 2025 levels.
This shift is visible first and foremost in the world’s largest markets. China installed an estimated 365 GW in 2025, with annual PV demand expected to decline from this peak level. According to EUPD Global Energy Transition GET-Matrix^©, in the United States (U.S.), installations are estimated at around 48 GW in 2025, marginally lower than approximately 50 GW in 2024, with additions expected to decline further in 2026 as incentive eligibility, trade enforcement, and permitting timelines increasingly shape deployment activity. Europe also recorded a decline, with installations in the 69 GW range in 2025, compared with over 70 GW in 2024, reflecting cooling residential demand alongside higher borrowing costs and tighter lending conditions.
While select Asian markets and the Middle East and North Africa (MENA) continue to expand, their growth is insufficient to offset deceleration across these core economies. As a result, global deployment momentum is increasingly determined by developments in mature markets rather than by headline growth in emerging regions.
At the same time, global manufacturing capacity continues to outpace deployable demand. Large-scale capacity build-outs in China and India now materially exceed domestic absorption, embedding structural surplus into the global PV market and reinforcing sustained downward pressure on pricing and margins.
Against this backdrop, energy storage is moving to the center of new system deployment. Grid congestion, curtailment risk, and price volatility are accelerating storage adoption across residential, commercial and industrial (C&I), and utility-scale segments. For C&I system owners, storage increasingly serves as a tool for mitigating exposure to volatile power prices, reducing dependence on grid supply during peak or constrained periods, and safeguarding long-term energy cost predictability. As a result, the ability to integrate storage is no longer optional, but is increasingly influencing whether projects proceed at all.
Together, these dynamics frame the global solar market entering 2026: a market no longer defined by uniform volume expansion, but by regional divergence, structural oversupply, and a growing emphasis on system integration and execution quality.
China: Demand stabilization, manufacturing surplus, and the rise of storage
China’s solar PV market has entered a phase of stabilization following years of rapid expansion. Installations are estimated at approximately 365 GW in 2025, indicating a clear plateau at historically high levels. Looking ahead, annual PV demand is expected to remain broadly within a range of 320–350 GW from 2026 onward, reflecting evolving grid conditions, regulatory adjustments, and system integration constraints.
While this sustains China’s position as the world’s largest solar demand market, domestic installations are no longer sufficient to absorb the country’s manufacturing base. Even at breakeven capacity utilization rate of 60%, China’s module capacity remains several times larger than annual domestic demand, structurally embedding surplus supply into the global market.
As a result, persistent surplus capacity continues to set the global price floor for PV modules, exerting sustained pressure on pricing across international markets and shaping competitive conditions well beyond China’s borders. However, China’s recent announcement to cancel the VAT export refund, reducing it from 9% to 0% as of April 1, 2026, could create a glimmer of hope for slightly less price pressure. In combination with recent increases in raw material and component costs, as well as rising silver prices, this development is expected to have a positive impact on PV module price levels in 2026.
At the same time, China’s domestic energy transition is increasingly shifting toward energy storage. Grid congestion, curtailment risks, and system balancing requirements under the 15th Five-Year Plan are accelerating battery storage deployment at a faster pace than PV additions. Storage and PV-plus-storage system integration are becoming central to project viability, redirecting domestic investment toward system-level solutions rather than standalone generation.
U.S.: Incentive tightening and trade barriers redefine market access
After a period of accelerated growth following the Inflation Reduction Act, the U.S. solar market entered a phase of adjustment in 2025. Changes in incentive eligibility, project timing rules, and trade enforcement have increased uncertainty across the development pipeline and reshaped deployment economics.
Annual solar PV additions are estimated at approximately 48 GW in 2025, down from around 50 GW in 2024, with installations expected to moderate further to roughly 43 GW in 2026 (read more here). Residential demand is normalizing as tax credit structures evolve, while utility-scale deployment is increasingly shaped by permitting timelines, interconnection bottlenecks, and heightened execution risk.
At the same time, U.S. module imports from Southeast Asia have declined sharply compared with 2024 levels. While imports from the region reached approximately 49 GW in 2024, shipments fell materially in 2025 as trade enforcement intensified and domestic manufacturing capacity expanded. Tighter scrutiny of supply chains linked to Chinese ownership, alongside uncertainty around incentive eligibility under Foreign Entity of Concern (FEOC) provisions, has reduced the availability of previously relied-upon imported supply.
Rather than enabling a smooth transition toward domestic sourcing, these dynamics are increasingly resulting in supply displacement and project delays, as portions of the import base become ineligible for incentives while domestic alternatives remain limited or higher-cost.
Battery storage remains structurally supported by grid integration needs, capacity markets, and growing commercial and industrial and utility-scale demand. As a result, storage deployment has proven more resilient than PV. However, uncertainty around localization requirements, incentive eligibility, and compliance obligations is increasing selectivity in project development and placing downward pressure on returns.
Europe: Stabilizing installations shift growth toward storage and execution quality
Following several years of accelerated expansion, Europe’s solar PV market has entered a phase of normalization. Annual installations have stabilized at approximately 65–70 GW since 2024, reflecting cooling residential demand and higher borrowing costs alongside tighter lending conditions across core markets such as Germany, Italy, and the Netherlands.
Europe’s demand mix is shifting decisively away from residential installations toward C&I and utility-scale projects. As rooftop incentives fade and grid export conditions tighten, growth is increasingly supported by corporate energy strategies, ESG compliance requirements, long-term cost considerations, and the commissioning of projects awarded in tender cycles.
This transition places EPC companies and C&I buyers at the center of market access, technology selection, and system integration, according to PV Commercial & Industrial EPCMonitor©. Procurement decisions are increasingly shaped by bankability, service reliability, regulatory compliance, and long-term partnership capability rather than headline equipment pricing (see Brand Leadership & Sustainability Rating – Europe).
In parallel, energy storage has moved to the center of Europe’s market momentum. While solar PV growth slowed across several major European markets in 2025, battery storage installations expanded sharply, with capacity estimated to exceed 29 GWh, representing an increase of more than 36% compared to 2024 levels, according to the EUPD Electrical Energy Storage Report© H2 2025. Rising occurrences of negative electricity price hours, growing grid stabilization requirements, and a stronger focus on maximizing on-site consumption are reinforcing storage as a core system component rather than an add-on.

India: Rapid manufacturing expansion adds to global oversupply
India’s solar PV manufacturing capacity is expanding at a pace that significantly exceeds the growth of domestic installations. While annual PV demand is expected to remain in the range of 40–45 GW, announced and under-construction module capacity continues to scale well beyond what the local market can absorb.
Even at breakeven capacity utilization factor of approximately 65%, this capacity expansion would result in a structural surplus of roughly 90 GW per year by 2027, which would need to be absorbed outside the domestic market (read more here).
This surplus is being added to an already oversupplied global PV landscape, reinforcing sustained downward pressure on module pricing. Although Indian modules continue to trail Chinese modules in terms of price and, in many cases, efficiency, India’s rapid manufacturing expansion is nevertheless contributing additional volume into a market already shaped by persistent excess capacity, particularly from China. As a result, competitive intensity is increasing across export markets, with potential pricing pressure extending regionally and tightening margins globally.
Middle East: Utility-scale growth reinforces the central role of EPCs
Solar deployment across the Middle East continues to expand, driven primarily by centrally tendered utility-scale projects. Growth is supported by government-led procurement and long-term power purchase agreements, with deployment paced by tender schedules rather than supply availability.
Market access in the region is defined by execution capability and bankability, placing EPCs and developers at the center of project delivery and supplier selection. While component pricing remains relevant, success increasingly depends on financing alignment, delivery track record, and the ability to execute at scale under strict timelines.
As a result, Middle East functions as a selective, execution-driven market, offering limited scope for opportunistic volume placement despite continued growth.
In this context, EUPD Research in cooperation with pv magazine is organizing the EPC | Project Developer Awards & MENA Leadership Reception alongside the World Future Energy Summit. The invitation-only event will take place on 13 January 2026 at Aloft Abu Dhabi, bringing together senior EPC executives, project developers, and energy leaders from across the region.
Conclusion: From 2025 signals to strategic positioning in 2026
The global solar PV industry is entering a phase where scale alone no longer guarantees competitiveness. Manufacturing capacity continues to expand, but market access is tightening, pricing pressure is becoming structural, and deployment outcomes are increasingly shaped by policy design, execution capability, and system integration rather than by volume targets.
With demand in China peaking, installations in the U.S. and Europe constrained by trade rules, financing conditions, and project execution timelines, and energy storage becoming a prerequisite for project viability, the cost of pursuing volume-led strategies without clear market positioning is rising sharply. Oversupply is no longer cyclical, but embedded in the global market structure.
In this environment, competitive advantage will be defined by how effectively companies choose markets and segments, align early with regulatory and compliance requirements, integrate storage and system-level capabilities, and build partnerships that secure durable access to projects. Achieving this increasingly depends on data-driven market intelligence and structured market prioritization, areas where EUPD Research supports manufacturers and system suppliers in translating complex market dynamics into actionable strategy.
For manufacturers and system suppliers, the next phase of the solar market will reward speed, focus, and disciplined execution. Leadership will belong not to those who pursue scale indiscriminately, but to those who identify where value is emerging and move first with the right technology, positioning, and market intelligence.
About the Authors:
Markus A.W. Hoehner is the Founder and Chief Executive Officer of the EUPD Group and Hoehner Research & Consulting Group. With more than 30 years of experience in renewable energy market intelligence, sustainability strategy, and international consulting, he has built the EUPD Group into a globally leading provider of research, certification, and industry platforms. Markus advises stakeholders worldwide on market trends, strategic planning, and decarbonization pathways. He can be reached at [email protected].
Daniel Fuchs is the Chief Customer Officer of EUPD Group. He has extensive international experience in sales, marketing, customer engagement, and strategic event management within the renewable energy and cleantech industries. His work focuses on building customer-centric growth strategies, strengthening global partnerships, and supporting market development across the solar, energy storage, and sustainability sectors. He can be reached at [email protected]
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From pv magazine Australia
An IEA survey of solar power applications in Australia shows that the country installed 5.2 GW of solar capacity in 2024 and reached a total of 40 GW, including 26.1 GW of distributed systems and 13.4 GW of centralized installations.
Utility-scale installations of 5 MW or more contributed 2 GW, while rooftop systems across residential, commercial and industrial sites contributed 3.2 GW to the annual total.
Solar installations in 2024 exceeded the cumulative total of all installations completed up to the end of 2015, which stood at 5.1 GW.
“Despite recording a record volume of installations in 2024, Australia did not rank among the world’s top ten markets for annual installations. This marks the second consecutive year outside the top 10, a position it has held since the IEA photovoltaic power systems program (PVPS) began tracking markets in the 1990s,” said the IEA.
For rooftop solar Australia outranks most nations, with 44% of free-standing homes having systems installed, including about 50% of homes in Queensland and South Australia.
“With low insolation relative to the rest of Australia (3.7 kWh per year), Tasmania has only 20% of free-standing homes powered by solar PV,” said the IEA. “South Australia, with a population of 1.77 million, rooftop solar alone has routinely been sufficient to power the state with excess power from rooftop and large scale being exported to neighboring states for over the four hours around mid-day.”
A trend toward larger residential systems has prompted a reclassification of typical system sizes. Residential installations were previously defined as 10 kW or less, up from 3 kW in 2012, and are now defined as up to 15 kW. Commercial systems are classified between 15 kW and 100 kW.
The report notes that Australia’s ambition for utility-scale solar falls into the 10 GW to 30 GW range. Despite incentives such as the Capacity Investment Scheme and its 40 GW target, issues related to connection approvals, congestion management and fragmented access arrangements increase costs and risks for grid-scale projects, the report finds.
Australia ranks in the top ten globally for total installed capacity and records a world-leading installation rate of more than 1.52 kW per capita.
“With an impressive total 26.1 GW of distributed solar and an additional 13.4 GW total centralized solar, combined with excellent insolation, solar power now meets over 20% of the nation’s total electricity demands,” the report says.
The National Survey Report of PV Power Applications in Australia 2024 lists University of New South Wales Australian Centre for Advanced Photovoltaics Director Professor Renate Egan as the lead author, with contributions from experts at six other Australian universities and clean energy specialist businesses.
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From pv magazine Australia
The Sunman Group, founded by solar pioneer and University of New South Wales (UNSW) alumnus Zhengrong Shi, has announced it will develop Australia’s largest solar module manufacturing plant in the Hunter Valley after landing AUD 171 million ($111.92 million) in federal and state government funding.
The Australian Renewable Energy Agency (ARENA) has committed up to AUD 151 million in conditional funding through the federal government’s AUD 1 billion Solar Sunshot program to support the development of the Hunter Valley Solar Foundry, while the NSW government has invested $20 million.
Sunman already has two manufacturing facilities: a 1 GW facility in China and a 500 MW facility that is under construction in the United States.
The proposed Hunter Valley facility, to be built at Black Hill near Maitland, will draw on Sunman’s established technology and track record as a lightweight solar innovator to manufacture 500 MW of solar modules annually for use in the Australian and international markets. The facility will initially produce 300 MW of panels per year before scaling up to the full 500 MW annual capacity.
“Once established, the Hunter Valley Solar Foundry will be the largest manufacturer of solar photovoltaic modules in Australia, and the only one in NSW, delivering world-leading products to residential, commercial and utility customers around the country,” Shi said.
Tindo Solar is currently recognised as the only manufacturer of Australia-made solar panels. The South Australia-headquartered company is in the process of scaling the annual output of its Mawson Lakes facility in Adelaide’s northern suburbs from 20 MW to 180 MW and is also investigating the potential of establishing a manufacturing plant capable of producing 1 GW of solar panels annually.
Sunman’s Hunter Valley Solar Foundry is expected to produce a range of solar modules, including the company’s proprietary enhanced Architecture Ready Composite (eArc) modules, that replace traditional glass with durable polymers. The flexible eArc modules are 70% lighter than conventional glass panels and can be moulded and glued to surfaces.
The facility is also expected to produce glass solar modules, develop a solar innovation hub to support the commercialisation of new solar technologies and operate as a solar manufacturing foundry with the ability to provide production capacity to original equipment manufacturers, further strengthening Australia’s domestic solar supply chain.
“This is an important milestone in Australia’s energy transition,” Shi said. “It has been my long-held ambition to establish solar module manufacturing in Australia, and it is my hope that over time the foundry supports the foundation of a vertically integrated solar supply chain in Australia.”
ARENA Chief Executive Officer Darren Miller said the new Hunter Valley facility will help build Australia’s solar manufacturing capability, reduce reliance on imports and expand the nation’s role in global clean energy supply chains.
“Deployment of solar photovoltaics at scale is central to meeting our long-term emissions goals,” he said. “Building our manufacturing capabilities will help ensure that our supply chains are resilient and Australian innovations are supported as we accelerate the rollout of solar PV.”
Construction of the facility is expected to generate up to 200 jobs, with another 100 ongoing roles once operational.
The funding announcement comes after local Sunman subsidiary Energus, earlier this year, received AUD 1.3 million in funding through the Solar Sunshot program to support a feasibility study for a 50,000 tonne per annum solar-grade polysilicon production facility in the Hunter Valley.
The study was to assess the technical, commercial, and environmental viability of producing high-purity polysilicon in Australia.
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Solar energy technologies can be vulnerable to cyberattack through inverters and control devices that are designed to help manage the electric power grid. Operating-technology (OT) devices like solar photovoltaic inverters, when connected to the Internet, are at higher risk relative to stand-alone OT devices. They must be able to prevent, detect, and respond to unauthorized access or attack. While some cyberattacks manipulate information-technology (IT) systems, cyberattacks on electric-grid devices can cause physical impacts like loss of power and fires.
The electric grid is becoming increasingly digitized and connected, so maintaining cybersecurity is a top priority for the U.S. Department of Energy (DOE). There are daily attempts to attack the grid, but the majority are not successful. In March 2019, however, hackers breached a utility’s web-portal firewall, causing operators to lose visibility of parts of the grid intermittently for 10 hours.
You may envision lone hackers furiously entering commands in dark rooms, illegally breaching and controlling sensitive systems, but many cyberattacks are more ordinary. For example, phishing scams use emails that appear to come from reputable sources and trick people into giving important information to a malicious actor. This type of manipulative, fraudulent practice is called social engineering. Failure to recognize such deceptions is the entry point into many systems. 
Outdated software is another risk: A novice hacker could take advantage of a system’s known vulnerabilities by running code downloaded from the Internet to attack it. Advanced hackers might discover problems so new that they’re called “zero-day attacks,” meaning security professionals have had no time to prepare for them.
A cyberattack on a cyber-physical system is different from one on an enterprise IT system because of the physical consequences. Cyber-physical systems are engineered systems that are built from, and depend upon, the seamless integration of computation and physical components.
Historically, cyber risk for solar was relatively minor, given how few systems were deployed and because most solar inverters did not communicate for monitoring or control. However, as more solar is installed and inverters become more advanced, this risk grows. Inverters are the interface between solar panels and the grid. If the inverter’s software isn’t updated and secure, its data could be intercepted and manipulated. An attacker could also embed code in an inverter that could spread malware into the larger power system.
A cyberattack that introduces instabilities or false information into the power system can cause physical as well as financial damage. For example, a security breach could make an unauthorized change in power delivery. Unauthorized changes to inverter controls or communications like these are called cyber-physical security breaches, because the result is a change in the voltage or the electric current that the inverter injects into homes or the grid.
Microgrids are also a potential target for cyberattacks. Microgrids are local power systems that can operate independently of the larger grid in case of a power outage. Protecting them from cyberattack becomes part of an overall resilience strategy to maintain critical electrical infrastructure in emergencies.
The introduction of widespread digitization and interconnectivity across the modern grid presents a great challenge for grid operators. As more solar and other distributed energy resources (DER) are added to the grid, so are more tools that provide utilities with real-time solar power generation and other information. These tools must be secured, or the grid will become more vulnerable to cyberattack.
Security software can help utilities maintain control of their DER and prevent attackers from injecting false information into the system. Most attempted attacks on the grid are mitigated by intrusion-detection software that alerts grid operators to abnormal behavior.
Utilities and solar system owners and operators can use a dynamic survival strategy based on defense-in-depth measures, which are basically diverse layers of security that cover everything from individual components to entire systems. For example, installing anti-virus software in DER systems, such as solar inverters and battery controllers, is one layer of protection. Installing virus protection and detection on the firewalls and servers that integrate DER into the broader system of grid operation is another layer. This strategy for DER is complex, considering the number of owners, operators, and systems involved, but it’s crucial to reduce the chance of cyberattack.
The DOE Solar Energy Technologies Office (SETO) is working to ensure the electric grid is smart, secure, and capable of integrating more solar power systems and other DER. SETO has developed a Roadmap for Photovoltaic Cybersecurity, supports ongoing efforts in DER cybersecurity standards, and is involved in the Office of Energy Efficiency and Renewable Energy (EERE) Cybersecurity Multiyear Program Plan and DOE’s broader cybersecurity research activities.
Learn more about the SETO’s systems integration research and its cybersecurity technology research, including the Securing Solar for the Grid (S2G) project.
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Scientists may have identified one of the Solar System’s most important “planet factories” hidden just beyond Jupiter.
When the Solar System first formed, the young Sun was surrounded by a sprawling disk of gas and dust. Over millions of years, tiny grains within that disk collided and merged into larger rocky bodies called planetesimals. Some of these objects eventually grew into planets, while others became the ancestors of today’s asteroids.
Researchers have long suspected that this process was messy and uneven rather than orderly. Different parts of the early Solar System likely evolved under different conditions, and planetesimals at various stages of development may have formed at the same time.
Now, scientists from the Max Planck Institute for Solar System Research (MPS) in Germany say they have identified a particularly important region just beyond Jupiter’s orbit. According to a new study published in The Astrophysical Journal, this ring-shaped area served as both an efficient and highly versatile birthplace for planetesimals.
Their computer simulations suggest that over a period of about two million years, the region produced planetesimals with dramatically different compositions.
“Different types of planetesimals apparently formed in the same region of the early dust and gas disk, only at different times. The region just outside Jupiter’s orbit offered excellent conditions for this,” said Joanna Drążkowska, head of the Lise Meitner Group on planet formation.
The research focused on a time roughly two to four million years after the Solar System was born. By then, Jupiter had already swept up much of the material near its orbit, leaving behind a gap in the surrounding disk of gas and dust.
Scientists believe that this process also created a ring of increased gas pressure just outside Jupiter’s orbit. Dust particles drifting through the disk became trapped there, causing huge amounts of material to pile up. These dense collections of dust formed small clumps known as pebbles.
Earlier studies had already shown that pebbles inside these “dust traps” could quickly grow into planetesimals during the Solar System’s early stages. However, researchers did not know whether the same region could continue producing bodies with very different compositions over long periods of time.
Using advanced simulations, the team found that several distinct populations of planetesimals likely formed within this dust trap over millions of years. The results also closely match the characteristics of specific groups of meteorites discovered on Earth.
“For the first time, we have succeeded in accurately reproducing the results of laboratory studies of meteorites using computer simulations of the early Solar System. The meteorites serve, so to speak, as a touchstone for theories of planetary formation,” said MPS Director and cosmochemist Thorsten Kleine.
Meteorites are pieces of rock from space that survive their fall through Earth’s atmosphere. Most are thought to be fragments of ancient planetesimals that have remained largely unchanged since the Solar System’s earliest era.
The researchers concentrated on carbonaceous chondrites, a carbon-rich type of stony meteorite. Previous laboratory studies suggest these meteorites formed beyond Jupiter during the same period examined in the simulations.
Scientists divide carbonaceous chondrites into six groups based on their ages and compositions. Some are fragile and consist mainly of fine-grained material that easily crumbles apart. Others are stronger and contain visible inclusions embedded within finer material.
In the simulations, these materials corresponded to two different substances believed to exist in the young Solar System. One consisted of delicate dusty material, while the other was made up of more stable clumps that formed early in hotter regions before spreading throughout the disk.
“For our simulations, it was crucial to model the behavior and interaction of both materials on both small and large scales,” said Nerea Gurrutxaga, PhD student at the MPS and first author of the paper.
The models tracked both the collisions of individual particles and the large-scale movement of material through the massive gas disk. Particles could stick together, shatter apart, drift inward toward the Sun, or collect in dense regions.
The simulations showed that Jupiter acted as a stronger barrier for larger, sturdier particles than for tiny dust grains. Meanwhile, the creation of new planetesimals gradually consumed part of the available material.
Over time, these effects caused different mixtures of material to gather in the region beyond Jupiter’s orbit. As the balance changed, clearly separate generations of planetesimals began to emerge.
During the first 500,000 years, the amount of crumbly material initially declined before increasing again over the next million years. Eventually, two distinct populations of planetesimals appeared. One group consisted mostly of fragile material, while the other was dominated by more stable matter.
The researchers believe that even earlier meteorite types beyond carbonaceous chondrites may also have formed within the same dust trap.
“There is strong evidence that dust traps were the preferred birthplace of planetesimals in our Solar System,” said Joanna Drążkowska.
Reference: “Carbonaceous Chondrites Provide Evidence for Late-stage Planetesimal Formation in a Pressure Bump” by Nerea Gurrutxaga, Joanna Drążkowska, Vignesh Vaikundaraman and Thorsten Kleine, 22 May 2026, The Astrophysical Journal.
DOI: 10.3847/1538-4357/ae6104
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by CBS6 staff
NYSDEC Washington County Grasslands Wildlife Management Area.Endangered birds at center of ongoing debate over proposed Fort Edward Solar Farm (wrgb)

Washington County, N.Y. (WRGB) — A 100-megawatt solar project in Fort Edward has received state approval.
The New York State Department of Public Service announced Tuesday that the Office of Renewable Energy Siting and Electric Transmission issued a final siting permit to Boralex LLC for the Fort Edward Solar Project, a large-scale facility planned in the Town of Fort Edward.
State officials said the project will generate about 100 megawatts of emissions-free electricity, enough to power roughly 25,600 homes, and is expected to be operational by 2030.
The development is also projected to create about 120 construction jobs and a small number of permanent positions, while providing more than $14 million in community benefits through tax payments and agreements with local governments and schools.

Fort Edward Solar Map 2025{ }

In addition, DPS said residents collectively could see about $500,000 in utility bill credits over the first decade of operation.
The project has previously faced opposition from some environmental advocates, particularly over potential effects on grassland bird habitats.
“You can’t just give birds a map and say, ‘hey birds, here’s your new home,’” said Alex Fasulo, a wildlife advocate and Schuylerville farm owner who previously criticized the proposal. “This specific grassland is where they have chosen to breed and feed for thousands of years.”

Short-eared Owl flying in the Washington County Grassland Bird Conservation Center. Photo by{ }Gordon Ellmers

State regulators said the approval followed a detailed review process that included public hearings and revisions to reduce impacts on farmland, wetlands, and wildlife habitat.
According to the Department of Public Service, the final project design reduced its footprint and environmental impacts, including cutting affected wildlife habitat and agricultural land by hundreds of acres.
Local leaders praised the project as a balance between economic development and environmental stewardship.
Town of Fort Edward Supervisor Tim Fisher said the process involved years of collaboration and adjustments to reflect community input.
“After years of thoughtful engagement and collaboration, the Town of Fort Edward is pleased to see the Fort Edward Solar Project receive its final siting permit," said Fort Edward Supervisor Tim Fisher.
Grassland Bird Trust and Boralex sent this statement to CBS6:

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Published on May 27, 2026
Joel Mairura
Enbridge has secured new off-takers as it operationalized phase one of its 815MW Sequoia solar farm project in Texas. Beverage and snacks giant PepsiCo and filtration products and solutions provider Donaldson Company have joined the list of power off-takers of the 815-MW project. Enbridge announced this along with the commissioning of the project’s first phase.
Moreover, PepsiCo and Donaldusn have committed to procuring green electricity from the complex. The plant already has long-term power purchase agreements (PPAs) with other companies. These include telecommunications company AT&T and also the North American unit of Japanese carmaker Toyota. Sequoia Solar is being installed in Callahan County, southeast of Dallas, at an investment of $1.1bn.
The initial phase added 400 MW of overall capacity. On the other hand, the remaining 415 MW will be installed in stage two. The whole photovoltaic (PV) complex will be completed by the end of this year. Once done, it will become one of the largest solar sites in North America. Earlier last year, Enbridge celebrated the completion of its first solar facility in Texas, the Orange Grove solar project. Currently, the 920-acre facility generates clean electricity for the ERCOT grid, supported by a long-term Virtual Power Purchase Agreement with AT&T.
The scope of implementation on the Sequoia solar farm in Texas features various aspects. On hardware and technology, approximately 1.8 million solar modules will be utilized. These include Runergy solar panels, Nextracker Horizon single-axis trackers, and Sungrow inverters. Installation will also leverage on automated robotic arms to lift and place the heavy solar modules.
The project is being carried out in a phased Rollout with the 815 MW capacity is being implemented in two stages. The first 400MW phase went live in late 2025 and has commenced operations this week. On the other hand, the remaining 415 MW is scheduled for completion and full commercial operation in phase two. The generated power connects to the ERCOT market via Lone Star Transmission’s new Reata substation.
Initial operations focus strictly on direct-to-grid solar generation without on-site storage. However, Enbridge is actively monitoring the electrical load of nearby data centers. Moreover, the developer may integrate a Battery Energy Storage Systems (BESS) based on future local industrial demand.
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COLUMBUS — The Ohio Supreme Court on Tuesday issued a mixed ruling regarding the construction of a massive solar farm in Madison County, sending the case back to state regulators to better evaluate how the project will look to the public.
The state’s high court affirmed most of the Ohio Power Siting Board’s decisions regarding the Oak Run Solar Project. However, the justices reversed a portion of the board’s approval because the developer failed to provide the required visual sketches and photographic simulations of the planned substations.
Justice Pat Fischer wrote the majority opinion, stating that state regulators did not get the necessary visual descriptions from the developer. The court ruled that the board needed these images to properly evaluate how the project would affect views from public vantage points.
The legal challenge was brought by a coalition of local governments, including the Madison County Board of Commissioners and the trustees of Deercreek, Monroe, and Somerford townships. Local officials argued that state regulators approved the project without gathering enough information to make an informed decision.
While the court’s majority rejected most of the local governments’ arguments regarding water safety and wildlife, the decision temporarily halts full approval until the visual data is reviewed.
The Oak Run project is designed to be a first-of-its-kind solar farm that combines renewable energy production with active farming, an approach known as agrivoltaics. The planned facility would span more than 6,000 acres of agricultural land in rural Madison County, southwest of Columbus. It is also slated to feature a battery-energy storage system consisting of 328 large battery containers across roughly 11 acres.
The court’s decision highlighted deep divisions among the justices regarding how much information a utility developer must provide before receiving a state construction certificate.
In a partial dissent, Justice Jennifer Brunner argued that the court should have also required the developer to submit baseline water-quality measurements and comprehensive wildlife surveys before the project could move forward. Brunner noted that the construction involves grading approximately 500 acres of farmland, which could cause soil erosion into nearby streams that flow into the Big Darby Creek watershed.
Brunner also expressed concern over the safety plans for the large battery facility, which is expected to use lithium-ion technology. Evidence presented during the case showed that if the battery facility catches fire, it cannot be easily extinguished with water and must be allowed to burn out. Such fires can release hazardous gases into the atmosphere.
The developer had promised to submit a detailed emergency-response plan to the state later and to provide equipment and training to local firefighters. The state board originally approved the project on the condition that those promises be kept.
Brunner criticized that approach, writing that expecting local governments to wait for vital safety information amounts to shifting the legal burden away from the developer. She argued that environmental data and safety plans should be fully reviewed by the public and regulators before construction is authorized, rather than letting a company figure out the details as the project evolves.
The high court’s majority maintained that state law allows regulators to issue certificates with conditions that developers must meet later during construction. The court found that the lack of baseline water and wildlife studies did not legally prejudice the local governments because other evidence suggested minimal impacts. The lack of visual models, however, violated explicit state administrative rules.
The case now returns to the Ohio Power Siting Board. Regulators must obtain the missing photographic simulations and sketches from the developer and conduct further proceedings to address the visual impacts of the project on the surrounding community.
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The lead researcher said the developed solar cell had achieved a highest power conversion efficiency of 0.61 per cent and demonstrated operational stability up to 250 hours. The result represents a proof of concept rather than a commercial product and highlights the potential of natural pigments for low-cost, low-impact energy harvesting. The team emphasised that performance optimisation and extended endurance testing remain priorities.
The dye was obtained from Gulabbas petals using standard extraction methods and incorporated into the photoactive layer to sensitise the cell to visible light. The research note explained basic characterisation of the pigment and device behaviour under laboratory illumination conditions, reporting reproducible but modest output levels. Attention was paid to material selection and simple fabrication techniques to keep processing environmentally benign.
Researchers at CUJ indicated ongoing work to improve efficiency and to study long-term stability under varied temperature and light regimes. The team intends to refine dye extraction, optimise interface layers and document performance over extended durations to assess practical viability. The team noted that collaboration with departmental colleagues and students supported the laboratory work. The project is presented as a contribution to sustainable materials research and to training students in renewable energy experimentation.
A team from the Department of Energy Engineering at the Central University of Jharkhand (CUJ) has developed an eco-friendly solar cell that uses a plant-based natural dye extracted from the petals of Mirabilis jalapa (commonly known as Gulabbas or Four O’Clock Flower). The researchers described the work as part of ongoing laboratory studies to explore sustainable alternatives to conventional photovoltaics. The device builds on dye-sensitised solar cell concepts adapted for locally available botanical materials. The lead researcher said the developed solar cell had achieved a highest power conversion efficiency of 0.61 per cent and demonstrated operational stability up to 250 hours. The result represents a proof of concept rather than a commercial product and highlights the potential of natural pigments for low-cost, low-impact energy harvesting. The team emphasised that performance optimisation and extended endurance testing remain priorities. The dye was obtained from Gulabbas petals using standard extraction methods and incorporated into the photoactive layer to sensitise the cell to visible light. The research note explained basic characterisation of the pigment and device behaviour under laboratory illumination conditions, reporting reproducible but modest output levels. Attention was paid to material selection and simple fabrication techniques to keep processing environmentally benign. Researchers at CUJ indicated ongoing work to improve efficiency and to study long-term stability under varied temperature and light regimes. The team intends to refine dye extraction, optimise interface layers and document performance over extended durations to assess practical viability. The team noted that collaboration with departmental colleagues and students supported the laboratory work. The project is presented as a contribution to sustainable materials research and to training students in renewable energy experimentation.
The awards will honour contractors and infrastructure companies delivering excellence in highway construction, safety, quality and project execution.RAHSTA Awards 2026 has officially opened nominations for the Contractors category, recognising the companies driving India’s highway and infrastructure expansion through world-class project execution and construction excellence.As India accelerates the development of expressways, tunnels, bridges and access-controlled corridors, contractors are playing a critical role in ensuring timely delivery, quality standards, safety compliance and sustaina..
India’s road construction sector is facing pressure from two sides. On one side is the West Asia crisis, which has pushed up the cost of oil-linked inputs such as bitumen, diesel and logistics. On the other is the persistent problem of negative bidding, where contractors are quoting sharply below project estimates to secure work.Together, these forces are creating a serious risk for project viability, execution quality and contractor survival.To read the full article Click Here ..
In construction disputes, claims for damages arising out of delay and prolongation often involve components such as head-office overheads, loss of profit and other indirect costs that are inherently difficult to quantify with precision. In such circumstances, tribunals and courts have, over time, accepted formula-based approaches such as the Hudson, Emden and Eichleay methods as tools to estimate such losses. To read the full article Click Here ..
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Home → Science → News
A stubborn crack in the station's oldest Russian module is bleeding air into space, and engineers are running out of patches.
For a brief, hopeful moment earlier this year, it seemed the International Space Station had finally stopped hemorrhaging. After more than half a decade of chasing hairline cracks through one of its oldest Russian modules, NASA announced in January that the pressure inside the troublesome transfer tunnel had reached what engineers called a “stable configuration.” Translation: the leak, at last, appeared to be plugged.
The relief lasted about four months.
On May 1, while Russian cosmonauts were unloading supplies from the Progress 95 cargo ship, sensors picked up a familiar, dreaded signal — a slow, steady drop in pressure inside the small vestibule known as the PrK module, a narrow corridor that connects a docking port to the venerable Zvezda Service Module. The leak was back. Or, more accurately, it had never really left.
NASA confirmed the news this week, with agency spokesperson Josh Finch telling Ars Technica that data analysis indicated a loss of roughly one pound of air per day. Roscosmos, the Russian space agency, has since allowed the pressure in the tunnel to gradually decrease, monitoring the slide and topping it up with the occasional puff of nitrogen and oxygen.
“There are no impacts to station operations,” Finch said, “and NASA and Roscosmos are coordinating on next steps.”
That phrase — coordinating on next steps — has become something of a running theme aboard the world’s most expensive piece of real estate.
The story of the leak begins in September 2019, when cosmonauts first noticed that the station was losing air faster than it should. Inspections eventually revealed the cause: microscopic structural cracks, almost too small to see, threading through aging metal that has now spent nearly three decades baking, freezing, and dodging micrometeoroids in low Earth orbit.
For years, engineers tried sealant after sealant. The patches helped, but not enough. By 2024, the leak rate had doubled, from one pound a day to a little over two, and NASA quietly escalated the issue to the top of its internal risk matrix.
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Publicly, NASA has tended to downplay the danger. Internally, the tone is rather different. According to Ars Technica, in meetings, officials have used the words “catastrophic failure.”
Roscosmos, for its part, has managed the problem the old-fashioned way: by keeping the hatch to the leaky module sealed shut most of the time, essentially quarantining the offending section from the rest of the orbiting laboratory. It is the spaceflight equivalent of closing a door on a draft and hoping the house holds together until you can sell it.
The trouble is that the house may not be sold on schedule.
The ISS is officially due to retire in 2030, after which a SpaceX-built deorbit vehicle will guide its roughly 450-ton mass into a controlled plunge over an uninhabited stretch of the South Pacific. But NASA and the U.S. Congress are now openly weighing whether to push the date back to 2032, or possibly further, to avoid leaving a gap in America’s permanent human presence in orbit before private replacements are ready.
That extension would require buy-in from the station’s international partners, Russia included. And it would mean asking some of the oldest modules in space — pieces of hardware launched when The Phantom Menace was in theaters — to keep holding pressure for years longer than they were designed to.
A NASA safety advisory panel warned earlier this year that the station is entering what it called the riskiest period of its existence. The returning leak is precisely what the panel had in mind.
NASA’s plan for life after the ISS hinges on a handful of private companies — including Axiom Space, Vast, Voyager, and Blue Origin — building their own orbital outposts that the agency can rent space on, the way it now rents seats on SpaceX’s Dragon capsule. The transition has not gone smoothly. In March, NASA floated a revised plan at its Ignition event that would have commercial modules dock onto the ISS itself before going independent, an idea that landed with a thud among industry partners.
The companies say they will be ready by 2030. They worry that every extension of the ISS chips away at the market they have been promised. And they have a powerful argument on their side: the station is, quite literally, leaking.
“This further confirms the wisdom of the current policy of retiring the ISS in 2030 and replacing it with more modern, more cost-effective, and safer commercial platforms,” Phil McAlister, NASA’s former director of commercial spaceflight, told Ars Technica.
For now, the astronauts and cosmonauts aboard the station are safe and the leak is being managed pound by pound. But the message from that small, stubborn pressure drop is hard to mistake. The International Space Station, humanity’s greatest off-world construction project, is getting old. And the question is no longer whether it can be patched. The question is how gracefully it can be retired before the patches stop holding.

A space nerd and self-described grammar freak (all his Twitter posts are complete sentences), he loves learning about the unknown and figures that if he isn’t smart enough to send satellites to space, he can at least write about it. Twitter: @JordanS1981
© 2007-2025 ZME Science – Not exactly rocket science. All Rights Reserved.
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Researchers from the German Aerospace Center (DLR) have conducted techno-economic analysis of producing n⁺-type polysilicon on oxide (POLO) back junction (BJ) solar cells in Germany and have concluded that the associated costs and benefits could be significant compared with photovoltaic cells manufactured using passivated emitter and rear cell (PERC) technology.
“We conducted the research in collaboration with the Institute for Solar Energy Research Hamelin (ISFH), Centrotherm and German technology company LPKF,” the research’s lead author, Juan Camilo Gómez Trillos, told pv magazine. “We analyzed the production costs and minimum sustainable price of the emerging POLO BJ cells with n+-type passivating poly-Si on oxide (POLO) rear contacts, assuming its production under industrial conditions and analyzing from cell production costs down to electricity generation costs. The POLO BJ concept allows higher efficiencies for photovoltaic cells compared to concepts without passivating contacts. In addition, the POLO BJ concept has certain advantages compared to the cell concepts in the market, such as lower silver consumption allowing lower production costs, or leaner process flow.”
The scientists explained that, although PERC has largely been replaced by tunnel oxide passivated contact (TOPCon) technology, the POLO BJ concept offers advantages over TOPCon. These include the use of aluminum-based metallization instead of high amounts of silver and a shift toward all-back-contact designs. “The value of next-generation solar cell concepts should not be assessed solely in terms of efficiency, but also in terms of manufacturability and system impact,” said Gómez Trillos. “POLO BJ shows potential as a high-efficiency technology with tangible economic benefits across the value chain.”
In the study “The Cost of Ownership and Minimum Sustainable Price of POLO BJ Cells Produced in Germany,” published in Advanced Energy & Sustainability Research, the research team explained that POLO BJ cells may be easily produced with existing and slightly adapted PERC production lines, with only one additional laser step being required.
The manufacturing process begins with a cleaned p-type silicon wafer, followed by the formation of a thin silicon dioxide (SiO₂) layer on both sides. A heavily doped n⁺ polysilicon layer is then deposited using low-pressure chemical vapor deposition (LPCVD) and subsequently thermally oxidized. The front-side silicon dioxide layer is selectively removed using either wet chemical processing or laser ablation, while the rear side remains protected during the texturing step. Passivation layers are applied using plasma-enhanced chemical vapor deposition (PECVD), and the process is completed with laser contact opening and screen printing to form the electrical contacts of the solar cell.
For their modeling, the academics assumed a production capacity of 5 GW and noted that, at this scale, a single plant could supply roughly 30% of Germany’s 2024 photovoltaic demand of 16.2 GW. A baseline POLO BJ cell efficiency of 24.2% was assumed, based on demonstrated industrial performance in M2-format devices, with a maximum scenario of 25% considered for sensitivity analysis. Plant output was evaluated under constant annual cell throughput, meaning higher efficiencies directly increase total peak power capacity. For comparison, PERC technology was modeled under identical conditions, including the same wafer format and plant size, but with a maximum efficiency of 23.1%.
Cost analysis was performed using a bottom-up cost of ownership model based on the guidelines of the Semiconductor Equipment and Materials International (SEMI) association and Germany’s mechanical engineering association VDMA. The model incorporated production tool costs, throughput, materials, and energy use. Minimum sustainable price was calculated to translate production costs into market-relevant pricing, including capex, opex, taxes, working capital, depreciation, and a weighted average cost of capital of 8%. Finally, levelized cost of electricity (LCOE) was estimated for utility-scale systems using POLO BJ and PERC modules.
The analysis showed that total investment costs differ moderately between the two cell concepts, ranging from $171.0 million for PERC to between $177.5 million and $182.1 million for POLO BJ. The main cost driver is the higher tool requirement for POLO BJ processes. When net working capital is included, total investments rise significantly, with POLO BJ-L becoming the most cost-efficient option. Variable and operational costs were also lowest for POLO BJ, with the main cost contributors being wafers and process materials, followed by labor and utility bills. Higher PERC costs, meanwhile, were found to be driven by its lower efficiency and higher cell demand.
Cost of ownership (CoO) analysis also showed clear advantages for POLO BJ concepts, with values of $0.0579–0.598/W compared to $0.0631/W for PERC. The minimum sustainable price (MSP) followed a similar pattern, with POLO BJ-L achieving the lowest value of $0.0716/W, while PERC reached $0.0775/W. Additional financial components such as taxes, capital costs, and operating expenses contribute significantly but do not change the relative ranking. Overall, POLO BJ became economically superior to PERC above certain efficiency thresholds. Finally, levelized cost of electricity (LCOE) analysis showed that POLO BJ-based systems reduce electricity costs compared to PERC in both Germany and Spain.
“The higher efficiency translates to lower LCOE at system level, which varies regionally,” said Gómez Trillos. “Under Southern European conditions, values of $0.0332/kWh were obtained for monofacial glass–backsheet modules and $0.0302/kWh for bifacial glass–glass modules. Furthermore, several aspects can influence the production costs and the minimum sustainable price of the photovoltaic cells. Local factors, such as electricity prices, labour costs, logistic costs, local corporate income taxes, or capital costs, can to a certain extent affect production costs at different locations. According to our analysis, only the labour and electricity costs would have together a share of 23% of the minimum sustainable price of POLO BJ cells in Germany. These factors can considerably fluctuate from country to country, leading to lower or higher results depending on the location.”
The researchers are convinced that POLO BJ cells represent a potential candidate for local production of PV cells in Europe. “During the project, we did not work on a concrete time frame for a potential implementation, but we are aware of projects dealing with the transfer of the knowledge on POLO technologies to the industry, which might result in concrete implementation in the following years,” Gómez Trillos concluded.
 
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6,000-acre solar project permit nixed by Ohio Supreme Court, for now at least  Ottumwa Courier
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Canadian energy company Enbridge has switched on the first phase of its massive $1.1 billion Sequoia Solar project in Texas.
Once both phases are complete, the Sequoia Solar project will reach 815 megawatts (MW), making it one of the largest solar farms in North America.
Sequoia Solar is in Callahan County, southeast of Dallas. Sequoia Phase One, which is now fully operational, adds 400 MW of solar capacity to the grid. Sequoia Phase Two will add another 415 MW and is expected to be completed by the end of the year.
The project is part of fossil fuel giant Enbridge’s broader push into renewable energy, as utilities and major corporations continue to lock in long-term clean electricity deals.
Enbridge’s Sequoia Solar will supply electricity to companies including AT&T, Toyota, PepsiCo, and Donaldson Company through long-term power purchase agreements.
Toyota said the project supports its Environmental Challenge 2050 plan, which aims to make all of its North American facilities carbon neutral by 2035.
AT&T will use electricity from the project to help lower energy costs and reduce emissions tied to its operations.
Texas continues to lead the US in large-scale renewable energy development, with solar and battery projects rapidly expanding across the state as electricity demand climbs.
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Over 4 GW of Chinese solar panels were imported into the Philippines between January and April this year, according to the latest report from energy think tank Ember.
Ember’s latest report uses Philippines customs data to highlight a growing surge in solar panel imports into the country.
Net solar imports stood at 3,130 MW in 2024, increasing to 5,068 MW in 2025 and reaching 4,133 MW over the first four months of this year, according to Ember’s figures. China has exported more solar panels to the Philippines this year than any other country except for the Netherlands, which acts as an import hub for much of Northwest Europe.
Ember’s report says the surge in solar panel imports suggests that rooftop solar deployment will begin to accelerate. The think tank analyzed generation data from electricity market operator IEMOP to calculate current rooftop capacity at around 1.3 GW, up from 721 MW towards the start of 2025.
“In 2025, the Philippines imported more than five times as much solar panel capacity as the grid-connected utility-scale solar it had installed. This implies a large inventory buildup that will translate into future installations,” the report explains. “The large step-up in Chinese solar panel exports shows that an even bigger gap is emerging.”
The report also found that rooftop solar’s payback time in the Philippines has crashed as electricity prices in the country soar.
Retail prices from electric power distribution company Meralco were 17% higher for retail customers, 18% higher for commercial customers and 14% higher for industrial customers in May 2026 than they were in May 2025. These increases make the Philippines home to the most expensive residential electricity price in Southeast Asia, as well as the second-highest commercial price and the third-highest industrial price. 
Ember says this upward trajectory has helped reduce the payback time for residential rooftop solar from 4 years in May 2025 to 3.1 years in 2026. Over the same time period, the payback time for commercial rooftop solar fell from 3 years to 2.3 years and from 3.9 years to 3.1 years for industrial rooftop solar.
The report suggests that these payback times should encourage mass uptake of rooftop solar, particularly when combined with policy changes designed to incentivize adoption, such as the easing of approval processes governing the country’s net metering scheme.
Dave Jones, Chief Analyst at Ember and lead author of the report, said the rapid rise of rooftop solar in the Philippines is “inevitable”.
“The government has an opportunity to carve its own path on rooftop solar, to pull the Philippines out of fossil dependency and onto a path of cheap, abundant electricity,” he said.
The report sets a target of deploying 3.5 GW of rooftop solar paired with 4.5 GWh of battery storage – matching the capacity under development in the country’s massive MTerra Solar project – within 24 months. It recommends several policy interventions required to unlock such scale, including expanding solar loan schemes, enabling smaller plug-and-play solar and introducing a government project to build batteries.
Ember’s report also highlights the emergence of domestic solar manufacturing in the Philippines.
Chinese trade data shows that $292 million of solar cells were exported to the Philippines between October 2025 and March 2026, up from almost nothing previously, equivalent to over 6.6 GW of capacity.
Large manufacturing facilities are beginning operations in the Philippines Economic Zone Authority, including a 1 GW manufacturing plant that opened in May 2025 and a second 1 GW plant that opened last month, both belonging to Singapore-based solar manufacturer Gstar.
The Philippines added 899 MW of solar last year, according to figures from the International Renewable Energy Agency (IRENA), taking cumulative capacity to over 3.8 GW.
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The Swiss Federal Council is aligning photovoltaic remuneration more closely with the market: from Jan. 1, 2027, distribution grid operators in Switzerland will be permitted to remunerate solar electricity based on the market price at the time of grid injection. With this measure, the federal government aims to create incentives to feed electricity into the grid when it is most needed. During periods of low prices, the electricity should instead be stored or consumed locally.
Grid operators will, however, retain the option of continuing to pay higher remuneration rates. Industry association Swissolar expects that many operators will choose to do so. The Swiss Federal Assembly approved the broad outlines of the new model in autumn 2025, and the Federal Council has now presented the detailed implementation framework.
For operators of small photovoltaic systems, the regulation includes investment protection in the form of a minimum remuneration premium. If the average quarterly reference market price falls below the statutory minimum remuneration rate, the premium will compensate for the difference for every kWh fed into the grid. The premium will be paid retroactively.
Swissolar noted that the new model could have significant implications for system operators, particularly those with low levels of self-consumption. These operators are expected to face greater exposure to low market prices during sunny periods. According to the association, this risk can be mitigated through the use of energy storage systems, which are becoming increasingly attractive as battery prices decline.
Models such as “Associations for Self-Consumption” (ZEV) and “Local Electricity Communities” (LEG) could also help reduce exposure to negative prices. Under these arrangements, solar electricity is consumed and traded locally within neighborhoods or districts instead of being sold via the grid operator on the wholesale electricity market.
According to Swissolar, efficient implementation of the new remuneration model will require easy access to market data. The association has therefore called on the Swiss Federal Office of Energy (BFE) to publish Swiss day-ahead electricity prices on its public dashboard and provide a freely accessible API for automated data retrieval.
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Residents, environmental groups and county leaders clash over growth, green energy and the future of rural Berkeley County.
CROSS, S.C. — Following passionate public testimony and a packed council chamber filled with residents from Cross and surrounding communities, Berkeley County Council voted Tuesday night to lift a large-scale development moratorium tied to a proposed solar farm in rural Berkeley County.
The 3-2 vote allows RWE Solar Development LLC, on behalf of Tall Corn Forestry LLC, to continue pursuing plans for the proposed Sandy Run Solar Project, an approximately 1,500-acre solar generating facility in Council District 7.
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The moratorium lift applies to roughly 7,521.79 acres of land tied to the proposal, though developers repeatedly stressed during the meeting that the solar project itself would only impact about 1,500 acres.
Council members Jarrod Brooks, Dan Owens and Amy Stern voted in favor of lifting the moratorium. Councilman Caldwell Pinckney and Councilman Marshall West voted against it. Councilmen Tommy Newell and Phillip Obie II recused themselves due to conflicts of interest, while Councilman Steve Davis abstained.
“I don’t want to hurt the people of Cross,” Davis said before excusing himself from the vote.
The decision came after one of the most heavily attended Berkeley County Council meetings in recent months, with residents voicing concerns about industrial development, property values, infrastructure strain and the future of rural Berkeley County.
Many residents who spoke during public comment said they believe lifting the moratorium could permanently change the Cross community.
“People have worked hard, and they’ve earned and saved money to buy their places in the country and want to know that they made a good decision and investment and don’t have to worry about what’s next door and what’s going to happen to their property values,” said Robert Barrett, a longtime Cross resident who opposed the project.
Several speakers opposing the project are also candidates running for Berkeley County Council seats this year.
Matt Hoover, a council candidate, warned about the long-term consequences of large-scale industrial projects in rural communities.
“This may be just another project to some, but for us, this is our home,” Hoover has publicly stated. “This is personal.”
Candidate Michael Parker argued the county’s own land-use protections should remain in place.
“If our county creates a moratorium and zoning protections, then those rules should apply equally to everyone — not just until someone with enough money wants them changed,” Parker told council members.
Parker also pointed to Berkeley County’s long-range comprehensive plan, which recommends maintaining the area’s rural character through 2040.
“District 7 contains some of the last remaining green spaces in this area,” he said. “Once that land is gone, it’s gone forever.”
Ralph Prioleau Jr., a longtime Democratic Party leader who is also seeking a council seat, urged council members to reject the request.
“These people have spoken,” Prioleau said. “What type of representative are you going to be tonight?”
While most speakers opposed lifting the moratorium, several environmental organizations publicly supported the project, arguing utility-scale solar is necessary to reduce reliance on fossil fuels.
Taylor Allred of the Coastal Conservation League told council members the Sandy Run proposal is one of the most environmentally responsible solar projects his organization has reviewed.
“The developer, RWE, has implemented all the conservation best practices that we recommend,” Allred said. “They did so without prompting and reached out to us more than a year ago for our input — the first developer to proactively do that.”
Allred said the project includes wildlife-permeable fencing, vegetative buffers, native pollinator plants and plans to avoid impacts to wetlands.
He also linked the proposal to broader environmental concerns involving fossil fuels.
“The greatest threat to wildlife is climate change,” Allred said. “And the Cross coal plant in this community is the largest in our state.”
Paul Black, speaking on behalf of the Sierra Club, also urged council to support the proposal.
“Berkeley County has a way to generate power that does not produce mercury, arsenic or heavy metals that poison the soil,” Black said. “And a way that would benefit the county.”
A representative from RWE pushed back against concerns raised by residents, insisting the project would have minimal impact on the surrounding community.
“Solar is a low-impact use of this land,” said Tory Kaso with RWE. “It will complement and respect the rural character of Cross.”
Kaso said the project site would remain heavily wooded and largely hidden from public view.
“The solar panels for Sandy Run will be located more than a mile from public right-of-way,” Kaso said.
She also disputed claims about the size of the proposal.
“Sandy Run will not cover 7,500 acres,” Kaso said. “The project will submit a development plan for approximately 1,500 acres — only the plan approved through the rezoning process can be constructed.”
RWE officials said the project would generate no odors, emissions or significant noise once operational and would place minimal strain on county services.
The company has also promoted economic benefits tied to the project, including more than $225 million in investment, over $45 million in projected county revenue during the project’s lifespan, more than 100 temporary construction jobs and up to eight permanent maintenance positions.
“The project will interconnect to the Santee Cooper grid and sell power through Santee Cooper, as South Carolina is a regulated market, and generation from the facility cannot be directly sold to a third party,” she added. “Finally, we will use modern solar panels, which are made of glass and aluminum. Those panels that we do use do not pose a public threat to health and safety. RWE will not change the Cross community.”
Councilman Caldwell Pinckney Jr., who represents Cross, delivered one of the night’s strongest arguments against the project.
“The decision is an easy one,” Pinckney said. “The truth has been spoken.”
Pinckney questioned whether the project’s benefits justified the scale of the development.
“They talked about the jobs,” he said. “As far as permanent employment, we’re talking about eight maybe at the most.”
Pinckney also argued the project would provide only a small portion of the state’s energy needs.
“Santee Cooper said what they’re offering is about 9 percent of what they need when it comes to energy,” he said. “Do the math. What’s the benefit?”
While he believes there needs to be alternative sources of power, Councilman Marshall West voted against lifting the moratorium.
“We need more power in the state of South Carolina,” West said. “But I’m not sure if this is the right project. I think this is a short-term answer to a long-term problem.”
Berkeley County Supervisor Johnny Cribb, who only votes if there is a tie, reiterated his opposition to large-scale solar projects in the county.
“I’m not against solar,” Cribb said. “I’m just against it in our county because of our reality with all the growth. Every homeowner is free to put solar panels on top of their home if they want to. It doesn’t have to go on 1,500 acres of land.”
Cribb suggested industrial rooftops could instead be used for solar installations.
“We have 25-30 million square feet of rooftops on industrial sites in this county,” he said. “If industries came in and wanted to put solar panels on top of their rooftops, nobody would be here complaining.”
Councilman Steve Davis, who stated he was a member of the Sierra Club, voiced support for solar energy generally but ultimately abstained from the vote.
“I believe in solar panels. It’s the future.” Davis said. “I try to live a simple life, but you can’t derail change. To negate this opportunity would be foolish to me because the people in the surrounding area are going to get credit off their light bill.”
Tuesday’s vote only lifts the moratorium and allows the project to continue moving through Berkeley County’s zoning and development review process.
Additional hearings, reviews and approvals will still be required before construction could begin.
Still, for many residents in Cross, Tuesday’s vote marked a major turning point in an increasingly emotional debate over growth, energy needs and the future identity of Berkeley County.
As the meeting adjourned, many residents left frustrated and concerned that rural portions of the county may continue facing pressure from large-scale development projects in the years ahead.
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The 1.1-megawatt (MW) ground-mounted solar array, located on a two-acre site east of Lot 560 on East Campus, is now operational. The project was approved by the Board of Regents in June 2024 and broke ground last April.
The array is expected to generate about 1.4 million kilowatt hours (kWh) of electricity each year—offsetting roughly 1% of CU Boulder’s total electricity use and saving an estimated $120,000 annually in energy costs.
“This project is another example of how CU Boulder continues to put campus climate action into practice through investments in our infrastructure,” said Chris Ewing, vice chancellor for infrastructure and resilience. “Through our ongoing campus sustainability efforts, we’re aligning investments toward meeting our climate action goals with delivering resilient infrastructure that will serve the campus for decades to come.” 
The project, delivered in partnership with contractor McKinstry, supports CU Boulder’s target to reduce greenhouse gas emissions by 50% by 2030 and achieve a linear reduction to zero emissions by 2050.
With the addition of the East Campus array, CU Boulder now has about 3.5 megawatts of solar capacity across campus, generating enough electricity to power the CU Events Center and Folsom Field combined. The new system is the university’s second ground-mounted array and complements 10 rooftop solar installations already in place.
This summer, CU Boulder will add another major installation when a 5-megawatt project being developed in Weld County through a partnership with Pivot Energy is completed.
 
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From June 1, solar projects must use only locally made cells: Why this raises concerns  The Indian Express
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From pv magazine Australia
The federal government has announced it will invest AUD 24.7 million over three years to deliver a national pilot for recycling solar panels that will help address the growing waste issues as they reach end of life.
The pilot program will establish up to 100 collection sites across the country, aiming to improve the management of end-of-life PV modules as Australia’s solar fleet continues to expand and mature. It will also support the development of a circular economy, allowing material and strategic minerals like copper, silver, silicon and aluminium to be recovered and reused rather than lost to landfill.
More than 4.2 million rooftop solar systems have been installed across Australia and an estimated 4 million panels are being decommissioned each year but government analysis shows only 17% of those panels are currently being recycled.
“Most panels are either stockpiled, dumped in landfill or exported for reuse,” Federal Environment Minister Murray Watt said. “These materials can be repurposed to support the clean energy transition and help reduce what we send to landfill.”
The government commitment comes after a Productivity Commission report into Australia’s circular economy recommended the government “urgently establish” a national recycling scheme for solar panels and investigate the merits of a similar scheme for electric vehicle batteries.
“Currently, neither solar PV systems nor EV batteries are managed in a consistent or comprehensive way once they are considered to have reached their end of life,” the report says. “Though some private recycling services exist in Australia … only 17% of solar panel components are recycled with the remaining 83% of materials treated as waste.”
The Productivity Commission said the key barrier to the growth of a solar recycling industry is the cost of recycling the panels, which it estimated is about six times the cost of sending them to landfill.
Darren Johannesen, executive general manager of sustainability at the Smart Energy Council, said the program would transform a growing waste challenge into a major economic opportunity.
“Solar panels are not a waste problem, rather a critical resource,” he said. “They contain precious materials like silver, copper, aluminium, silicon and high-grade glass, commodities critical to our clean energy shift.”
“Implementing a national stewardship scheme, which we hope and expect will follow the pilot, will trigger an urban-mining boom, and a new wave of smart energy investment in jobs and growth.”
The Australian government estimates the creation of a national product stewardship scheme for small-scale solar PV systems could unlock up to $7.3 billion in economic benefits through reduced waste and reuse of materials.
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Best of the Capitol 2026

Howard Fischer, Capitol Media Services//May 27, 2026//
Debate rages over state land designated for solar industry
Daniel Baldonado, a contract worker for a steel fabrication company, Ironco Enterprises, installs a series of solar panels on the roof of Wells Fargo Arena on Arizona State University’s Tempe campus. (Photo by Brandon Quester/Cronkite News Service)

Howard Fischer, Capitol Media Services//May 27, 2026//
The Hobbs administration has unjustly prioritized renewable energy projects over new housing projects, legislative Republicans contend.
Led by Rep. Ralph Heap, R-Mesa, lawmakers are one step away from approving legislation that would override a practice by the Arizona Land Department to study and make available a map where the agency believes its extensive holdings make the most sense for large-scale solar projects.
The caveat, said the Mesa Republican, is that the agency is not preparing similar maps for others who might want to buy or lease state lands. And that, he told Capitol Media Services, amounts to the agency “putting its thumb” on the scale in a way that gives solar projects more priority than housing.
“By designating a map for solar, but not for other industries, the Hobbs administration is effectively declaring solar the preferred use of the land,” he said in a separate statement in support of his legislation.
“For many residents, these parcels are among the worst possible locations for utility-scale solar: near established residential neighborhoods, directly in the path of growth, and on land that could otherwise support new housing,” Heap said. “At a time when housing affordability is a top concern for Arizonans – and when communities are increasingly frustrated with large wind and solar projects being placed in their backyards – Hobbs placing new renewable energy development in the heart of urban and suburban cores makes zero sense.”
The governor says she remains convinced that Arizona needs an “all of the above” approach for energy. And she said all she’s looking for is balance.
“I think that it is essential that we’re not picking winners and losers in the energy equation,” Hobbs said in response to questions by Capitol Media Services.
Hobbs says that the agency’s policies have only one guiding star: What raises the most money for the state. But that raises the question of whether the department could be skewing that evaluation.
For Heap, Exhibit No. 1 is that solar map.
But there is other evidence that there are decisions being made which are designed to encourage renewable energy projects on state lands.
“When the federal government acted to limit what they were going to approve on federal lands, we took the opposite action and said we’re going to expedite approvals on state land,” she said.
“And we’re doing that,” Hobbs said. “We have to ensure that we’re not limiting what we can use to power Arizona.”
The governor has said, however, that none of that puts the Land Department out of compliance with state requirements and guidelines for how to lease and sell state land.
“The number one responsibility of State Land, and the constitutional obligation, is to get the highest value of land for the trust,” Hobbs said.
When Arizona became a state in 1912 it was given about 10 million acres of land by the federal government to be held in trust.
Some of it has been sold off for development, leaving about 9.2 million acres, with about 8 million acres remaining for K-12 education. While there are outright sales, something pretty much required for new residential developments, the trust also can make money by leasing that property, including for grazing, some long-term commercial development as well as for mining.
It can also develop solar and wind energy.
All that gets figured into that constitutional requirement that state lands must be managed for its “highest and best use” and to maximize financial returns.
But Heap told colleagues during legislative hearings that the action of the Land Department, under Hobbs, to create the “solar scores map” skews all that.
“This map singles out solar development, often near growing communities in places like the greater Phoenix area while offering no comparable scoring and mapping for other critical uses like home building or mining,” he said. “This tilts the playing field towards one industry, risks lower value uses, and short-changes the funding our schools need.”
That’s where Heap’s HB 2975 comes in. It has a two-step approach: kill the ability of the Land Department to have a solar map and instead direct the agency to prepare similar maps, this time for residential and mining.
“This ensures neutral, data-driven decisions that prioritize the highest return for Arizona,” he said.
Hobbs, for her part, insists that’s what’s already happening with the actions of the Land Department when it decides who gets to lease or buy state lands.
“If the highest and best value of the land is renewable energy, that will be the case,” she said.
“If the highest and best use is housing, that will be the case,” the governor continued. “We’re not sacrificing one for the other.”
But Spencer Kamps, vice president of the Home Builders Association of Central Arizona, said it’s not that simple. He said that the decision of the Land Department to create a map for best places for solar – and only for solar – can affect who gets access to state land.
Kamps pointed to large areas on the map of available state lands which are color-coded as being the most suitable for solar. Many of these parcels are in lands on the edge of existing urban development, not just around the Phoenix area but also in Pinal County and both northwest and southeast of Tucson.
“In the absence of a similar map for other industries, some might say the solar map is serving functionally as a ‘presumptive highest and best use map,’ which gives solar a ‘rebuttable presumption’ of highest and best used in each part indicated in green,” he said in prepared comments.
HB 2975, which has been approved on a party-line vote by the Republican-controlled House and now awaits a Senate vote, has its detractors.
“It does single out solar in a punitive way,” said Sandy Bahr, director of the Grand Canyon Chapter of the Sierra Club, of the proposal to eliminate the solar map.
“It does not negate that very high responsibility of the state Land Department to determine what is the highest and best use and to maximize dollars for the trust,” Bahr said. “So I don’t know why you would want to get rid of that.”
Rep. Chris Lopez, R-Casa Grande, wanted to know whether it was appropriate to have things like large solar farms near residential development.
Bahr responded that there are multiple factors that go into such placement. But she said that proximity is not necessarily a bad thing.
“Generally, having that solar generation closer to where that electricity is being used is good,” Bahr said.
The measure also drew opposition from Chispa Arizona, a program of the League of Conservation Voters.
“We feel HB 2975 moves Arizona in the wrong direction and removes a useful planning tool,” said lobbyist Jodi Liggett.
Heap, a Republican candidate for the Arizona Corporation Commission, which regulates utilities, said his legislation he’s not trying to kill utility-scale solar.
“In fact, I don’t mind some solar,” he said. “You want some solar fields? I don’t have a problem with that.” But Heap said he wants to ensure that other uses, including residential and mining, also get a fair chance to buy or lease state lands.
There’s also the question of whether solar leases can impair residential development.
“They want to put all these solar fields out in Pinal County,” Heap said, referencing a plan to put in an 8,100-acre project on state land near Florence Junction.
“That’s definitely in the line of housing development,” he said.
“We say we want more housing,” Heap said. “But definitely the solar would negatively impact a lot of growth in that area.”
Heap was not alone in his concern about the project. It was unanimously rejected by the Pinal County Board of Supervisors.
The fight over the solar map at the Capitol doesn’t address parallel findings raised in a report last year by the Auditor General’s Office which said the agency has failed to properly plan for its land sales, including for residential development.
“For years, the department has failed to keep land and housing development moving with consistent long-term disposition planning and predictable decisions,” said Rep. Gail Griffin. The Hereford Republican chairs the House Committee on Natural Resources, Energy and Water.
“That means less trust revenue for classrooms and fewer lots available for homes,” she said. “The department can improve housing supply and education funding today by selling more land and ending the internal practices that keep projects stalled.”

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Solar power could soon be cheaper than natural gas power in Anchorage  Alaska Beacon
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From pv magazine India
India added 119 GW of solar module manufacturing capacity and more than 9 GW of cell capacity in 2025, according to a new report released by Mercom India.
The report attributes the capacity additions to strong demand from India’s utility-scale solar pipeline, residential rooftop targets under the PM Surya Ghar program, and the domestic cell mandate under the Approved List of Models and Manufacturers (ALMM) List II.
Cumulative module manufacturing capacity reached around 210 GW as of December 2025, while cell manufacturing capacity stood at about 27 GW. Of this, module capacity under ALMM List I totaled 173.1 GW, while cell capacity under ALMM List II was nearly 26.5 GW at the time of the report’s release.
“While 2026 is widely seen as the year domestic module and cell production will meet demand, our view is that alignment will occur later in the year. Domestic cell manufacturing capacity is expected to begin increasing after March, based on commissioning timelines and ahead of the ALMM domestic cell mandate taking effect in June. However, newly commissioned lines typically require around eight months to stabilize and achieve optimal yields. As a result, effective supply available to module manufacturers will increase more gradually,” said Raj Prabhu, CEO of Mercom Capital Group.
“Solar module manufacturing in India is ripe for consolidation. Declining mono PERC demand, lower utilization at smaller facilities, and rising capital requirements are shifting market share toward larger, integrated, and more efficient manufacturers,” Prabhu added.
India imported a total of 99 GW of solar modules and cells in 2025. Modules accounted for 25% of imports, while cells made up 75%.
Domestic manufacturers exported around 5 GW of solar modules in 2025, with the United States accounting for 96.8% of shipments. Cell exports totaled 192 MW, with the United Arab Emirates as the leading destination, accounting for 57% of exports.
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The gated driveway leading to the Guam International Country Club in Dededo on June 13, 2024.

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The gated driveway leading to the Guam International Country Club in Dededo on June 13, 2024.
A deal that would see a 57.4-megawatt solar farm on the old Guam International Country Club property selling energy to the Guam Power Authority is on hold, for now, with the Consolidated Commission on Utilities seeking more details about the agreement.
GPA presented a resolution to approve the 25- to 30-year energy purchase deal with a consortium of Power Solutions and Korea’s Top-Tier at a Tuesday evening CCU meeting.
But CCU Chairman Francis Santos raised questions about the agreement, which he said commissioners did not have enough time to review.
Santos said the agreement was a part of about 1,000 pages of documents for different projects that the CCU received the night before the meeting.
Commissioners tabled the matter and will come back next Wednesday to decide it.
Plans to turn the GICC golf course in Dededo into a solar farm have been in the public eye for years now, with the over 12-acre property sitting on CHamoru Land Trust property.
GICC was around $988,000 behind on rent at one point. A golf course-to-solar farm switch is meant to keep the lease going and money flowing to the Land Trust.
Despite opposition from multiple Dededo residents, the conversion has approval from the Land Trust and the Legislature.
But the solar consortium still needs a deal with GPA to actually provide the power before it can open. GPA will purchase energy from the solar facility, and then sell it back to power customers.
Besides four separate solar sites on the old Dededo golf course, the solar consortium will also put an almost 5 MW solar facility on a property near the back gate to Andersen Air Force Base in Yigo, GPA General Manager John Benavente said Tuesday.
“This facility actually will hook up directly to the … power plant and to an underground line right from the golf course to the area,” Benavente told the CCU.
Solar facilities will also come with 35.5 MW worth of batteries that can be used to store energy and shift it to nighttime use.
The total 62 MW from the golf course and Yigo solar farm will come on top of various other solar projects GPA has in the pipeline, Benavente said.
“With your award today, that will give us about a total of 357 MW of renewables with 146 MW of batteries,” he said. “All of this will basically be online in 2029.”
That solar capacity would bring GPA’s power generation capacity right up to about 50% renewables, according to the general manager.
More renewables would mean less need to raise the fuel surcharges for customers when oil goes above $120 per barrel, as it is now, Benavente said.
But Santos, during the discussion, said that GPA had not shown the resolution approving the deal to commissioners at a work session held last week.
“So this is the first time we’ve actually seen, and we’ll be able to discuss it,” Santos said.
It is common practice for the power authority to present resolutions to the CCU a week ahead of the meeting when the resolution will be decided. GPA leadership will sometimes present resolutions that aren’t ready ahead of time on the day of the meetings.
Benavente apologized for the delay in presenting the agreement, but said it was thoroughly reviewed.
He said the project was time-sensitive, and the solar operators would need to meet certain timelines to get tax credits.
Power Solutions and Korea’s Top-Tier have to start construction by July 4, GPA legal counsel Marianne Woloschuk added.
Chairman Santos also took issue with a still-pending easement agreement between GPA and the Land Trust for a power substation that will sit on just under an acre of the golf course property.
He said that detail was not communicated ahead of the Tuesday evening meeting.
Benavente said the substations will be operated by GPA, in perpetuity.
But power authority staff noted that the actual agreement for the substation was not yet approved by the Land Trust, and was on the CLTC’s agenda for a Thursday decision.
At one point during the meeting, Santos remarked of the solar consortium, “there was talk out there that they lost their backer.”
“Now they have a backer that’s great. Can we honestly say that you’ve done due diligence on the backer on the procurement team to come here?” Santos asked.
“I can honestly say, Mr. Chairman, that I believe that the way it’s set up, the approvals and reviews that we have made satisfies me that they can move forward,” Benavente replied.
Commissioner Michael Limtiaco suggested that the CCU recess their meeting and take more time to review the details of the solar deal.
Santos said he wanted a copy of the CLTC lease for the solar project.
Commissioners will come back at 5 p.m. June 3 to decide on the matter.
Reach reporter Joe Taitano II at JTaitano@guampdn.com.
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While we might want alternative sources of energy, we also should not accept the destruction of land of land for solar panels. Remember Marbo Cave? Put the darn things on the rooftops of existing hotels and commercial buildings and those under construction. Put them on paved parking lots, like garage-shelters. Stop destroying land for lucrative contracts. I hope neighbors are keeping good lawyers and reach out to national and international organizations that can help them hold the contractors and agencies liable for health and safety when the illnesses, lack of sleep and other harms start surfacing. Is it worth the risks? Let’s see who goes on record.

They (CLTC and the Legislature) should’ve proposed that property to better use like the development of housing for the underserved people of Guam! The housing ownership housing is a big crisis that the government is totally ignoring.

Honestly, I don’t trust Francis Santos nor JB.
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Researchers from Taiwan’s National Cheng Kung University and Chung Yuan Christian University have developed an interface-engineering strategy to overcome key efficiency bottlenecks in mesoporous perovskite solar cells by introducing APTS-functionalized reduced graphene oxide (APTS-rGO) into the electron transport structure.
In this work, reduced graphene oxide (rGO) was chemically modified using 3-aminopropyltriethoxysilane (APTS), a silane coupling agent with both amine and silane functional groups. This dual functionality enables strong bonding with oxide surfaces such as TiO₂ while simultaneously improving compatibility with the perovskite layer.
The APTS modification allows precise tuning of the rGO electronic properties. Kelvin probe analysis confirmed a shift in work function from 4.567 eV to 4.148 eV after functionalization, improving band alignment between the electron transport layer and the perovskite absorber. This adjustment reduces interfacial energy barriers and promotes faster electron extraction.
Beyond energy alignment, the APTS-rGO layer also enhances interfacial contact and reduces defect-mediated recombination. Graphene’s inherently high carrier mobility – up to 25,000 cm²/(V·s) in ideal conditions – supports efficient charge transport, while the functionalized surface improves interfacial bonding and stability.
When integrated into mesoporous TiO₂-based perovskite solar cells, the APTS-rGO layer led to notable performance gains. The optimized devices achieved a Voc of 1.04 V, Jsc of 19.9 mA/cm², FF of 70.39%, and a PCE of 14.6%, corresponding to an 18% improvement over reference devices. The enhancements are attributed to reduced charge transfer resistance, minimized recombination, and improved carrier extraction efficiency.
This study reinforces the role of graphene derivatives as tunable, solution-processable interfacial materials and demonstrates how chemical functionalization can unlock their full potential in next-generation photovoltaic devices.

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A group of researchers from Germany’s Institute for Solar Energy Research Hamelin (ISFH) and MN Metall GmbH, a German sheet metal processing specialist,has developed a PV-activated design façade element with aluminum as base material.
“The project has also other partners such as Baltic Renewable Partners GmbH & Co. KG, and Fraunhofer CSP,” corresponding author Kevin Meyer told pv magazine. “We are developing the new aluminum facade elements with integrated PV modules as part of the AluPV project, which is funded by Germany’s Federal Ministry for Economic Affairs and Energy (BMWE).”
The proposed approach involves directly laminating a PV module onto the aluminum facade element. “We were able to develop a lamination process that allows the PV module to be laminated into the 3D structure of the facade element,” Meyer went on to say. “Due to the high linear thermal expansion coefficient of aluminum, direct lamination poses challenges regarding the bending of the facade elements. This bending was prevented by the design structure on the sides.”
Another challenge is the electrical insulation between the current-carrying solar cells and the aluminum. “Sufficiently high electrical insulation can be achieved by placing a polyvinyl fluoride (PVF) layer between the solar cells and the aluminum,” Meyer further explained. “We were also able to demonstrate the PV activation of various design variants, giving our developed prototypes a certain degree of variability.”
Overall, the prototypes of the PV-activated facade element ultimately differ from a facade element without PV by only two connectors. “For us, this is a key factor in ensuring that the prototypes will later be accepted and used by installers,” Meyer said. “The prototypes developed represent a first step toward a novel BIPV product that will hopefully increase the spread of BIPV and, above all, the use of building facades for PV in the future.”
In the study “PV Design Façade Element: Combining a PV Module With Aluminum Façade Elements,” published in Progress in Photovoltaics, the researchers explained that the proposed lamination process enables PV modules to be directly bonded onto aluminum façade elements with complex 3D profiles using a standard plate-membrane laminator.
Lamination is performed using a plate-membrane laminator at 155 C and 1,000 mbar, with silicone layers used to compensate for height differences in complex 3D designs. After lamination, all modules show high structural integrity with no air bubbles or visible delamination, with electroluminescence (EL) imaging confirming that no cracks or cell damage occurred during processing.
Three building-integrated photovoltaic (BIPV) modules were fabricated on differently shaped anodized aluminum sheets, all sharing the same internal PV stack. BIPV-1 uses a flat 1 mm aluminum backsheet, while BIPV-2 adds 15 mm folded edges to improve stiffness, and BIPV-3 incorporates additional 2 cm high 3D structural features with a central flat PV area.
The module stack consists of ethylene vinyl acetate (EVA) encapsulant layers, a PVF insulation sheet, crystalline silicon solar cells interconnected with copper wire, additional EVA layers, and a 3 mm front glass cover.
The BIPV-3 module was found to eliminate bending while maintaining electrical performance and was selected as the preferred design for the construction of the façade element prototype, which the scientists dubbed BIPV-4. This module builds on the BIPV-3 design but introduces improvements such as rear junction boxes, insulated cross-connectors, a zigzag 3D structure, golden anodized aluminum, and optimized use of M12 cells. A reference module with a PET-backsheet is fabricated using a nearly identical PV stack to enable performance comparison.
Overall, the prototype demonstrated in testing that aluminum-based façade-integrated PV can match conventional module performance while maintaining safe electrical isolation.
The group designed multiple PV design façade variants with adaptable cell formats. The designs include different surface geometries such as wave, zigzag, and rectangular structures, demonstrating flexibility in aesthetic and structural concepts. One variant even features dual PV-active areas and customizable color options tailored to architects or building owners.
The scientists also claim that the proposed system can also be scaled to different module sizes, up to 2 meters, allowing integration into diverse façade geometries. “We were able to demonstrate the variability of our PV-activated design façade element,” they concluded. “It was variable in color, size, cell type, cell size, and in the shape of the design structure. We could therefore address important criteria for the acceptance and integrability of BIPV modules with our aluminum-based PV-activated design façade element.”
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Through the window of his combine, Wayne Greier watches his teenage son Blake drive a tractor across an empty field, towing a plow into position for another uncertain season of spring planting.
Greier would be worrying less if the solar farm he wanted on his land had come to pass. But local officials blocked it in 2023 under an Ohio state law, and Greier – facing a heavy medical debt – had to sell part of his land to stay afloat. The deal that was killed would have brought him about US$540,000 (RM2.1mil) in lease payments every year.
“It was our saving grace,” he said. “It wasn’t a scary picture that everybody likes to paint about solar and the loss of farmland.”
Local opposition to solar has long been an obstacle for green energy developers. But some communities are working to reverse local restrictions, citing the tax benefits and jobs the projects bring and the lease payments from energy companies that can provide stable income to farmers in a volatile industry.
When a solar company approached him wanting to build panels on part of his land, Greier, 42, and a sixth-generation farmer, hesitated. But facing US$1mil (RM3.95mil) in medical debt from a long battle with Covid and related complications, he saw a chance to save his farm.
Some in the community thought differently.
Greier said he and his family were ostracised as debate over the project played out in public meetings. His mental health plummeted. And the project was eventually blocked under a state law that allows counties to block construction of wind and solar farms on land they deem “restricted”.
“I was the one that was going to lose the sixth-generation farm. I was the one that couldn’t provide for my family,” he said.

President Donald Trump's hostility to green energy has battered the industry by wiping away subsidies, loans and tax incentives. But even before his return to the White House, local bans on renewable energy were becoming more common. A 2025 study from Columbia University found that from 2023 to 2024, there was a 16% increase in local laws across 44 states that restricted such projects.
But, she added, “When it’s your community and your backyard, balancing these processes so people feel like they’ve had a say without creating so many veto points that nothing can get done, I think is the trick. And it’s not easy to do.”

In February, Dearborn County, Indiana officials paused solar development for a year after concern from residents over the proximity of solar panels near homes and potential environmental impact of panel materials.
Bobby Rauen, who lives near part of a proposed 1,200-acre (486ha) solar project in that county, is among residents who petitioned for the pause. He said he hopes officials use this time to create better protections for residents living near potential solar projects. He said he was also concerned that farmland may not go back into production if solar panels are eventually removed.
As a member of the Renewable Energy Farmers of America, Greier, who primarily farms corn and soybeans, has shared his experience with lawmakers, advocacy groups and in communities debating green energy development.

He recently spoke to government officials at a public meeting in Richland County, Ohio, about 100 miles (161km) from his home. Advocates there got a referendum on the ballot this May to reverse the county’s ban on wind and solar projects.
Morgan Carroll, a lifelong county resident, has been working since last summer to rally support to drop the ban. Though she is not a farmer or landowner, Carroll said she supports the jobs and tax revenue these projects can bring and thinks the ban takes the decision away from residents – and may someday affect her two young children.
“I want them to be in a county that can provide jobs, can provide a good school for them,” she said. “I don’t want to have to move.”
Congressional Republicans and the Trump administration moved up deadlines for utility-scale solar projects to qualify for tax incentives after the passage of a big tax breaks and spending cuts bill last July. Now, utility-scale solar projects have to be in service by the end of 2027 to qualify.

But after a Garrard County ordinance was passed in 2023 restricting the development of solar, the energy company Leavell was working with decided to end the project.
Leavell, who said she is a Republican, questioned why lack of federal support for green energy projects should affect her ability to pursue these projects on her own land. She and a group of six other landowners are suing to overturn the ordinance.
“The thing I guess that perplexed me so much is that there’s so many more worse things that could be next to you,” she said.
Carroll, who helped gather signatures for the referendum in Richland County, Ohio, found that when the debate over solar projects was framed as a property rights issue, people in the community were more receptive.
Greier also focuses on property rights when speaking on the issue. His farm is his retirement plan, and he should have the right to use it to support his family, he said.
“There’s families that are relying on this and looking for this,” he said. “And it’s been taken away, this opportunity.” – AP
 
 
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The JinkoSolar Tiger Neo 3.0, new N-type high-efficiency module, with a peak power output of up to 670 W, a module conversion efficiency of 24.8%, and a bifacial factor of up to 90%, has amassed a backlog of around 20 GW since its official launch last November and is expected to become one of the manufacturer’s best-selling panels this year. This module sets a new performance benchmark for the industry. The production facility has an annual manufacturing capacity of 40 GW.
To date, JinkoSolar has filed over 5,700 patent applications globally, with more than 3,500 valid granted patents, ranking first in the industry in terms of patent volume. The manufacturer’s high-efficiency N-type monocrystalline TOPCon cell conversion efficiency has reached 27.79%, steadily approaching the theoretical limit of 28.7%. Regarding next-generation perovskite tandem cell technology, JinkoSolar has achieved an efficiency breakthrough of 34.76%, laying a solid foundation for future mass-produced products.
The Tiger Neo 3.0 includes four core technological breakthroughs:
The Tiger Neo 3.0 not only achieves breakthroughs in power and efficiency but also demonstrates outstanding performance in key metrics such as high-temperature operation, low-light conditions, and long-term reliability. Designed to provide stronger and more stable green power for global utility-scale solar plants, commercial and industrial (C&I), and residential scenarios, this marks a new stage in the industrialization of N-type technology.
Core advantages of the Tiger Neo 3.0 module include: a high front-side power of up to 670 W with a conversion efficiency of 24.8%; a bifacial factor of 85% (±5%); a temperature coefficient of -0.26%/°C; a linear degradation rate of only -0.35%; excellent anti-shading and hot-spot prevention capabilities, and outstanding low-irradiance performance, maintaining a relative power of 95%-98% under 200 W/m2 irradiance.
JinkoSolar’s Tiger Neo 3.0 module is widely applicable across diverse scenarios. It is not only suitable for utility-scale solar plants where its high bifaciality can bring extra power yields, but its extreme low-light performance can also generate more returns for users in C&I and residential rooftop scenarios.
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From pv magazine Australia
Rooftop solar generation in Australia reached an all-time high of 4,407 MW in the fourth quarter of 2025, up 8.7% on the same period in 2024. The increase also reduced daytime operational demand, supported battery charging, and contributed to a new overall renewable energy generation record of 51% in Australia’s NEM.
Distributed solar output in the quarter rose by 353 MW compared with the fourth quarter of 2024, averaging nearly 30 MW more than grid-scale solar, which achieved 324 MW above its output in the fourth quarter of 2024 and set a new quarterly record of 2,535 MW, up 149 MW (+6.3%) from the grid-scale solar record in the first quarter of 2025.
Exceptional peaks were recorded, with distributed solar reaching 16,319 MW during the half-hour ending 12:30 p.m. on Wednesday, Dec. 3, 2025, an 8.9% increase on the previous record in the fourth quarter of 2024 of 14,980 MW.
Grid-scale solar reached a new half-hourly output record of 8,148 MW during the interval ending 10:00 a.m. on Monday, Nov. 24, 2025, up 8.1% from the previous peak of 7,536 MW set in the first quarter of 2025. In October 2025, renewable potential exceeded 100% in 55 half-hour intervals, compared with 13 intervals in October 2024.
“It demonstrates that more wind, solar and battery capacity in the system reduces reliance on higher cost coal and gas generation, placing sustained downward pressure on wholesale electricity prices,” said AEMO Executive General Manager Policy and Corporate Affairs Violette Mouchaileh.
Wholesale electricity prices averaged AUD 50 ($35)/MWh across the NEM, a reduction of AUD 39/MWh (-44%) from the fourth quarter of 2024 and AUD 37/MWh (-43%) from the first quarter of 2025.
Western Australia’s Wholesale Electricity Market (WEM) also recorded high renewable and storage generation. Total WEM solar installations rose from 0.4 million at the end of 2020 to 0.6 million at the end of 2025, while CER solar capacity increased from 1.6 GW to 3.0 GW. Distributed solar generation in the fourth quarter of 2025 increased by 46 MW (+7.8%) compared with the same period in 2024.
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California advocates wanted to provide solar panels to 1 million low-income housing residents. After ten years, the state is more than 900,000 short of that goal.
Photo by Gabrielle Lurie/San Francisco Chronicle via Getty Images
Governor Gavin Newsom has dismissed fossil fuels as “alternative energy,” and wants to power California with, among other things, the sun. Through extensive mandates and extra energy costs for non-solar consumers, the Newsom administration has directed billions to building solar energy capacity.
The centerpiece of this initiative is the Solar on Multifamily Affordable Housing (SOMAH) program. SOMAH began under Governor Jerry Brown, who signed legislation requiring a state commission to apportion up to $100 million a year from California’s cap-and-trade program to pay for the installation of solar panels on apartment buildings in poor areas. Since then, California has devoted nearly $900 million to SOMAH, which the state hoped would create 300 megawatts of power by 2030 and advocates envisioned would create a million solar-using renters.
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The results have been disastrous. Since 2015, the program has installed or reserved only 129 megawatts of solar power for approximately 65,600 residents—nowhere close to the target of 1 million “solar renters.”
What happened? First, incompetence. For a decade, businesses and utilities have been forced to buy emissions credits, and while the state has lavished nearly $900 million on SOMAH, administrators designed the program so poorly that they have paid out only $131 million for solar installation.
As the program’s largest contractor admitted in a draft audit, potential customers were turned off by the paperwork, bureaucracy, and red tape. “Initially, we found housing owners excited about the program,” the contractor said, “but after a long and laborious process, they are much less enthusiastic.”
That is an understatement. From the beginning, the SOMAH program has been plagued by delays and cancellations. More than 400 applications have wound up cancelled or withdrawn, or about a third of the total. On average, projects take three and a half years to make it through the program’s gauntlet of paperwork and inspections.
Some projects have been fully installed—only to sit idle for a year or more waiting for permission to begin operating. As a result, more than $700 million of the program’s budget remains unspent. In other words, California can’t even give away a heavily subsidized, and sometimes free, product.
These failures do not mean, however, that no one is profiting. The managers of the SOMAH program have spent about $60 million on overhead, including salaries, conferences, website development, and more. And, as part of that budget, they have devoted at least $5.5 million to “community-based organizations” (CBOs), most of which are left-wing nonprofits that, in one case, labeled giving solar panels to low-income housing residents a way to fight “racial injustice.”
Under the guise of marketing and outreach, SOMAH paid more than $163,000 to the Asian Pacific Environmental Network (APEN). Vivian Yi Huang, the group’s co-director, extolled the need to “fight against the systems of white supremacy, patriarchy, and capitalism of the extractive economy.” The organization called for Richmond, California to “Defund the Police and Invest in Black Lives” and is a member of the Defund Police Coalition in Oakland, California.
California Environmental Justice Alliance (CEJA) told supporters that it “led in the creation” of SOMAH. Officials awarded it $230,000. The nonprofit wants the “democratization” of “land, labor, and resources” to “reverse the long course of environmental racism, the climate crisis, and colonialism.”
CEJA uses aggressive language to support its apparent goal of banning oil. “What’s at stake is our very survival,” its then-executive director said in 2021. “We must make the transition to 100 percent clean energy and bring all communities along to avoid a devastating climate apartheid.”
The group’s political arm, CEJA Action, endorses candidates and publishes voter guides as it “builds the political power of communities of color to advance environmentally and socially just policies.”
While APEN and CEJA no longer partner with the state, one of the active CBOs, Communities for a Better Environment, is no less radical. Last year, the group demanded the immediate release of everyone who was detained in immigration raids in California. “[T]here is no environmental justice without migrant justice,” the group wrote. “[W]e stand in solidarity with migrant, low-income, queer and trans, and people of color.”
Have these groups delivered results? No.
In 2023, a state-contracted auditor interviewed some CBOs. It found that they were only “responsible for a handful of submitted applications.” This year’s draft audit noted an “inverse relationship” between new applications and spending on these groups.
The other main beneficiary of the SOMAH program is a San Francisco-based corporation called Sunrun Inc., which bills itself as the country’s largest solar provider and has been the contractor for 78 percent of all SOMAH projects. The company has donated hundreds of thousands of dollars to political candidates—including $50,000 to Gavin Newsom’s campaigns—and has employed an army of lobbyists in Sacramento.
Newsom, in turn, has packed his administration with former Sunrun employees. The governor appointed the company’s public policy manager to the California Energy Commission and appointed its former chief policy officer to a regional water quality control board. In recent years, Sunrun representatives have met with government regulators’ offices to discuss SOMAH, including last December, when the company supported efforts to expand the program.
SOMAH and Sunrun did not respond to requests for comment.
California’s infrastructure projects seem always to fall short. SOMAH shows why. Liberal nonprofits help pass sweeping climate laws and receive money from the programs those laws create. In turn, those groups use their expanded influence to push for still more mandates and spending. The laws finance the activists, the activists demand more laws, and the cycle feeds itself—and helps well-connected firms, like Sunrun, collect new contracts.
Meantime, Californians increasingly think solar isn’t worth the headache. As one property owner told auditors, it’s “hard to justify poking a whole bunch of holes in your roof all over the place, just for a small amount of benefit.”
Christopher F. Rufo is a senior fellow at the Manhattan Institute, a contributing editor of City Journal, and the author of America’s Cultural Revolution. Austen Hufford is a senior investigative reporter at City Journal.
City Journal is a publication of the Manhattan Institute for Policy Research (MI), a leading free-market think tank. Are you interested in supporting the magazine? As a 501(c)(3) nonprofit, donations in support of MI and City Journal are fully tax-deductible as provided by law (EIN #13-2912529).
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From pv magazine Australia
A new report from the Clean Energy Council (CEC) shows Australian homes and businesses installed 2.6 GW of new rooftop solar capacity during 2025, including 1.5 GW in the second half of the year, boosting the overall total to 28.3 GW.
The latest edition of the CEC’s half-yearly Rooftop Solar and Storage Report shows 139,080 rooftop PV units were installed in the six months to the end of December 2025 with total installations for the year reaching 254,664.
Rooftop solar’s contribution to total electricity generation also continued to climb, reaching 14.2% in the second half of the year, up from 13.4% in the same period the previous year.
CEC Chief Executive Jackie Trad labelled Australia’s rooftop PV uptake a “national triumph,” saying the combined capacity of the country’s small-scale solar now eclipses the country’s entire fleet of coal-fired generators, which total 22.5 GW.
“Our biggest power station now resides on the rooftops of more than 4.3 million households,” Trad said. “It not only leads our national renewables rollout but also leads the rest of the world on a per capita basis.”
While the overall tally climbed to 28.3 GW, rooftop solar installation volumes eased year on year, down 15% on 2024 when 300,375 PV systems were installed, a result the CEC suggested showed the market is reaching critical mass and a shift towards energy storage.
“This was the first time since 2020 that total annual rooftop PV installations did not surpass 300,000, suggesting we have now passed the peak of rooftop PV installations as consumers turn their demand towards small-scale batteries,” the report reads.
Trad said recent government home battery programs, including the federal government’s $7.3 billion (USD 5.14 billion) Cheaper Home Batteries program launched on 1 July, have “strapped a rocket” to Australia’s distributed energy storage sector.
“We’ve seen phenomenal uptake of home batteries in Australia, with installations more than doubling in the space of one year,” she said. “Australian households have installed as many home batteries in the six months to the end of last year as they did across the previous five years combined.”
A record-breaking 183,245 battery units were installed in the second half of 2025, a four-fold increase compared to the same period in 2024.
The six-monthly total is equivalent to 99% of sales made between 2020 and 2024 and took the total number of battery installations across Australian households to 454,753 as at the end of last year.
The CEC said the growth of the small-scale market has exceeded expectations with rooftop PV capacity now expected to surpass the Australian Energy Market Operator’s projections for 2030 by 1 GW.
According to AEMO’s 2024 Integrated System Plan, distributed PV is projected to reach 36.1 GW of capacity in the National Electricity Market (NEM) by 2029/30.
This projection required an annual rate of 2.5 GW of newly installed rooftop solar from 2023/24 onwards. Over the past five years, the NEM has installed an annual average of 2.7 GW of rooftop PV.
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From pv magazine Australia
A AUD 1.2 million ($850,000) clean energy project conducted in Samoa will bring 108 households and five community centers on Upolu and Savai’i access to clean energy in support of communities located outside the country’s electricity grid.
On the island of Apolima, a mini-grid power network will also receive an upgrade to provide round the clock renewable electricity to 11 households.
The project is a joint initiative of the Samoan Electric Power Corp. (EPC), in partnership with the Samoan Ministry of Finance, the Ministry of Women, Community and Social Development (MWCSD), and supported by the Australian government’s clean energy initiative REnew Pacific.
The EPC will install the rooftop solar panels and battery energy storage systems on 88 homes that are not connected to the grid, while an additional 20 households will be supported through a fast track initiative with the MWCSD to ensure fair access for families facing barriers to applying or installing systems.
The five community centers (fales) will also receive solar and battery systems to allow residents, especially those unable to host clean energy technology, to charge phones, access lighting, and use shared appliances.

EPC General Manager Fesola’i Tau’ili’ili Faumui Iese Toimoana said at the heart of the project are Samoan communities – the families, elders and young people whose lives will be brighter and safer with clean energy.
“EPC’s collaboration with the Ministry of Finance and the Ministry of Women, Community and Social Development reflects the spirit of Samoa’s governance: partnership, service and inclusion,” Toimoana said. “Together, we are ensuring that energy access is not just a technical achievement but a social commitment. We aim to empower villages, strengthen resilience and honour the values that define us as a nation.”
EPC will own and maintain the system while offering community training and energy-use awareness sessions to help households use the new power safety and efficiently.
“We are deeply grateful to the Australian government for its trust and partnership. This first-ever Australian Infrastructure Financing Facility for the Pacific (AIFFP)-funded project for Samoa marks a milestone not only for the Electric Power Corp. but for our nation’s journey toward universal access to clean energy,” Toimoana said. “Through REnew Pacific, EPC will deliver reliable solar and battery systems to families who have waited the longest for safe power.”
REnew Pacific supports locally-led projects that provide off-grid renewable energy solutions to rural and remote communities across the Pacific and Timor-Leste.
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Business Hyundai Engineering breaks ground on Texas solar project
Published : May 28, 2026 – 11:46:22

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Hyundai Engineering said Thursday it had broken ground on the Hillsboro Solar Power Plant in Texas, marking its first overseas renewable energy development project managed from start to finish.
The groundbreaking ceremony was held Wednesday in Hill County, Texas, with executives from Hyundai Engineering, Hyundai Motor Group affiliates and local EPC contractors in attendance. Participants included Lee Seung-won, head of Hyundai Engineering’s energy plant business division; Peter Branham, chief operating officer of Hyundai Mobis Alabama; and Christopher Whitehead, chief administrative officer of Hyundai Motor Manufacturing Alabama.
The project is a milestone for Hyundai Engineering as the company led the entire development process, including securing permits, signing power purchase agreements and arranging project financing.
Hyundai Engineering secured $310 million in financing from four institutions, including the Industrial Bank of Korea.
The 200-megawatt solar power plant is scheduled to begin commercial operations in December 2027 and is expected to generate about 476 gigawatt-hours of electricity annually.
The company has accelerated its expansion into renewable and next-generation energy businesses as demand for low-carbon energy infrastructure grows.
Hyundai Engineering completed the Saemangeum onshore solar project in 2021 and was selected as a strategic partner for a 1-gigawatt solar power project in Serbia in 2024.
Beyond solar energy, the company has expanded into nuclear and hydrogen projects. It participated in the Missouri University Research Reactor project and established a water electrolysis-based hydrogen production facility in Boryeong, South Chungcheong Province.
“This project demonstrates our capabilities as an energy developer with expertise across the entire project cycle, from development and financing to operations,” a Hyundai Engineering official said.
“We will continue expanding next-generation energy projects in North America and Europe to strengthen our global competitiveness.”
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Floating solar farms could be significantly more efficient than solar farms on land thanks to the natural cooling effects of seawater, according to new findings from a comparative study conducted by researchers from the National Taipei University of Technology (NTUT) in Taiwan. The floating solar panels used in the study produced 12 percent more energy than the on-land models, with potentially huge implications for global energy security and decarbonization pathways.
The study, published this month in the Journal of Renewable and Sustainable Energy, compared the life cycles of an offshore floating photovoltaic (OFPV) in the waters off of Taiwan to a solar farm on the island. The study found that the OFPV system generated about 12 percent more energy in its lifetime thanks to the natural cooling effects of the seawater, which increased the system’s efficiency. Moreover, it found that OFPV also enhanced emission reductions.
“Because of this higher energy output, they also achieve greater carbon emission reductions,” study co-author Ching-Feng Chen, PhD, was recently quoted by Interesting Engineering. “In simple terms, even though both systems use similar technology, placing solar panels on water can make them more effective,” Chen went on to say.

This could have enormous implications for Taiwan, which is currently experiencing an existential energy crisis. Taiwan’s energy grid is totally isolated and strained, supporting a population of 23 million as well as an enormous and energy-intensive tech manufacturing sector with extremely limited land and energy resources. On top of that, Taiwan’s energy sector also faces major security threats from China and is simultaneously being battered by a still-unfolding energy crisis driven by the closure of the Strait of Hormuz.
At present, Taiwan is 99 percent dependent on imported natural gas. This renders the island extremely vulnerable to the kind of market shocks we’re seeing now due to the U.S.-Israel war in Iran. Asian markets have been hit extremely hard by the closure of the Strait of Hormuz, and Taiwan is no exception – in 2025 about one-third of the island’s liquefied natural gas imports came through the Strait. “For a country where gas-fired plants generate around half of all electricity, this is a direct hit to the fuel that was supposed to make Taiwan’s power system cleaner, flexible and secure,” Oilprice reported last week.
Taiwan desperately needs to update and diversify its energy mix, but the country’s small size and high population density pose major challenges for building out utility-scale clean energy resources. Solar and wind farms take up a lot of space, and Taiwan simply doesn’t have the land to spare. But what Taiwan does have a lot of is coastline. Offshore solar could therefore offer a lifeline to the island’s beleaguered energy sector.
As land-use conflicts surrounding renewable energy become more commonplace and more intense around the world, OFPV could offer a win-win for energy security as well as national security, within and beyond Taiwan. The potential advantages of the NTUT study extend to many other countries with similar land and population constraints.
“From a broader perspective, our work shows that offshore floating solar is not just a technical alternative but a strategic solution for other countries with limited land resources that can help expand their renewable energy capacity while still meeting environmental and land-use constraints,” Chen elaborated in a press release accompanying the study.
In fact, the idea of offshore solar as a lifeline for “population hotspots” is not a new one. In 2023, World Energy suggested that “vast arrays of solar panels floating on calm seas near the Equator could provide effectively unlimited solar energy to densely populated countries in Southeast Asia and West Africa.” The discovery that such solar panels can be even more productive than on-land models is just the cherry on top of this land-use issue.
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From pv magazine India
Indian state-owned coal miner Coal India Ltd has dissolved its solar manufacturing arm, CIL Solar PV Ltd, ending its proposed entry into integrated solar PV manufacturing.
In a regulatory filing, Coal India said the name of its subsidiary, CIL Solar PV Ltd, has been struck off the Register of Companies under Section 248(5) of the Companies Act, 2013, and that the company now stands dissolved.
The move follows a public notice issued by the Ministry of Corporate Affairs in April 2026, stating that the Registrar of Companies proposed to strike off or remove the name of CIL Solar PV Ltd under Section 248(2) of the Companies Act, 2013.
Coal India had established CIL Solar PV Ltd as a special-purpose vehicle (SPV) to develop a planned 4 GW solar PV manufacturing facility in India, covering ingots, wafers, cells, and modules.
The proposed gigafactory formed part of Coal India’s broader diversification strategy as it seeks to expand beyond coal mining into integrated solar PV manufacturing. The company has been entering the renewable energy sector to support the decarbonization of its operations. It plans to install 3 GW of renewable energy capacity by 2027-28 and 9.5 GW by 2029-30 across India.
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The Solar Ready Vets program has since expanded into the Solar Ready Vets Network. Click here to learn more about the Solar Ready Vets Network.
In 2014, the U.S. Department of Energy launched a pilot program, Solar Ready Vets^®, that connected our nation’s skilled veterans to the solar energy industry by preparing them for careers as solar photovoltaic (PV) system installers, sales representatives, system inspectors, and other solar-related occupations. In 2017, the pilot ended and Solar Ready Vets became an independent program administered by participating military bases, using a variety of tools and partnerships developed during the pilot phase while it was administered by The Solar Foundation. Altogether, the pilot program graduated 526 students from 35 cohorts in 10 different states across the country.
The Solar Ready Vets pilot program was enabled by the U.S. Department of Defense’s SkillBridge initiative, which allows exiting military personnel to pursue civilian job training, employment skills training, apprenticeships, and internships up to six months prior to their separation. The pilot program prepared soon-to-be inactive military personnel to be strong candidates for positions in management, PV installation, sales, and other technical and non-technical positions.
The Solar Ready Vets pilot program was developed based on the specific needs of high-growth solar employers and was tailored to build on the technical skills that veterans have acquired through their service. Each cohort trained approximately 20 active military personnel per class and each class lasted between four to six weeks. Programs included hands-on instruction that took place in a classroom setting, though some cohorts had a hybrid format of online and in-person classes. There were no out-of-pocket costs for participating service members or military bases.
Toward the end of the course, students took the North American Board of Certified Energy Practitioners (NABCEP) Entry Level Exam to earn the most widely recognized entry-level PV installation credential across the country. After graduation from a Solar Ready Vets pilot cohort, service members interviewed with leading national and regional solar companies for a wide variety of jobs within the industry.
Military bases were selected by DOE, in partnership with the U.S. Department of Defense and military branches, based on the number of exiting military personnel from the installation, the strength of the surrounding solar market, and the training capacity of nearby training institutions. The Solar Ready Vets pilot program was available at the following military installations:
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Solar owner stunned after rooftop panels suddenly produce more power than they thought possible  Yahoo Tech
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[SMM Photovoltaic: India's Uttar Pradesh YEIDA Zone Adding Combined 7GW of Solar Manufacturing Capacity] Uttar Pradesh Chief Minister Yogi Adityanath recently handed land allotment letters to 17 companies in the YEIDA region, with two large-scale solar manufacturing projects drawing particular market attention.
CESC Green Power Ltd. will establish a 3GW solar cell and module manufacturing facility on approximately 100 acres, with a total investment of around ₹3,805 crore. Integrated Batteries India Pvt. Ltd. will set up a 4GW solar cell manufacturing facility on approximately 25 acres, with an investment of approximately ₹1,146 crore. Together, the two projects add a combined 7GW of new solar manufacturing capacity.
However, SMM believes that India is expected to remain partially reliant on imported supply chains in the near term — particularly in polysilicon, wafers, and certain core manufacturing equipment, especially in upstream materials and high-end process machinery.
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Cuba’s energy crisis has reached critical levels as the island nation struggles to withstand a US blockade on oil imports used for power and transport. Cuba’s outdated, oil-dependent electricity grid now faces constant blackouts, especially after domestic reserves of diesel and fuel oil ran out in mid-May. Power plants burning domestically produced oil and natural gas, alongside solar capacity ramped up over the last two years, provide short windows of electricity supply during the day. The country has continued to import Chinese solar equipment in 2026 to further build out capacity, but has a long road to free itself from oil imports.

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At the start of 2026, I predicted that Africa would surprise a lot of observers with solar deployment this year. That was in my 2026 energy predictions article, and the prediction was not based on one giant solar park, one government announcement, or one development bank programme. It was based on a set of conditions that were starting to reinforce one another.
Cheap Chinese solar modules were looking for markets. Batteries were getting cheaper. African grids in many countries remained weak, unreliable, or incomplete. Diesel was still expensive. Mines, telecoms, warehouses, farms, factories, clinics, schools, and households all had practical reasons to want electricity that did not depend entirely on the grid or fuel trucks. At the same time, African trade integration, Chinese-built logistics corridors, ports, roads, rail, and local business networks were making it easier for physical hardware to move.
That was also the argument in my earlier Africa clean-energy flywheel article. The core idea was simple enough. Solar and storage imports lower the cost of reliable electricity. Better logistics move the equipment inland. The African Continental Free Trade Area makes cross-border trade and larger markets more plausible. Electrified transport creates new demand for electricity and batteries. Industrial development follows cheaper and more reliable power. Better markets reward better governance. None of that is guaranteed, but the pieces fit together better than most people outside the continent seem to notice.
The new data does not prove the thesis yet. It does something more useful. It tells us where to look.
The headline number going around is that Africa added a record 11.3 GW of renewable capacity in 2025, three times the prior year. That is a meaningful number. It is also easy to misuse. It is not a solar number. Large hydro and wind projects are doing real work in that total, and anyone who treats 11.3 GW of renewables as 11.3 GW of solar is already most of the way to a bad conclusion.
The solar-specific number is smaller, but more interesting. The Global Solar Council says Africa installed about 4.5 GW of new solar PV in 2025, up 54% year over year. That is not remotely India-scale. It is not Brazil-scale either. But the same assessment says Africa imported 18.2 GW of solar modules in 2025. That gap is where the story gets interesting.
A 4.5 GW reported installation number and an 18.2 GW module import number do not mean 13.7 GW of solar was secretly installed and nobody noticed. That would be too simple, and energy systems rarely reward simplicity. Some of those modules are inventory. Some are headed to projects that have not been commissioned. Some may be delayed. Some may be re-exported. Some may be sitting in warehouses waiting for financing, inverters, batteries, installers, interconnection, or customers.
But the mismatch is too large to ignore. Solar modules are physical objects. They arrive in containers. They sit in warehouses. They get bolted to roofs, fields, factories, telecom sites, mines, farms, clinics, schools, and mini-grid systems. They also often fail to appear quickly or cleanly in formal utility statistics, especially when they are behind the meter, off-grid, fragmented across many small systems, or used mainly to reduce diesel generator hours.
This is the difference between a visible energy transition and a real one. Visible transitions have auctions, grid connection agreements, government ministers in hard hats, and official commissioning reports. Real transitions also have procurement managers cutting diesel bills, mine operators buying power reliability, telecom firms reducing fuel deliveries, farmers installing pumps, and households buying panels because the grid is not worth waiting for. The first is easier to count. The second can move faster.
That is why the 20 GW prediction needs to be tested carefully. If the claim is that Africa will officially report 20 GW of new solar capacity in 2026, that now looks unlikely. It would require reported additions to jump from 4.5 GW to 20 GW in one year, or roughly 4.4 times. That kind of acceleration can happen, but usually where the policy, finance, grid connection, procurement, and reporting machinery is already working at scale.
India is the reference case for that formal pathway. India installed 36.6 GW of solar in 2025, with large-scale projects doing most of the work. India has a national solar market, national auctions, a large grid planning machine, and a reporting structure that can see most of what is happening. Africa does not, because Africa is not a country. It is many markets with very different grids, policies, utilities, currencies, customer bases, and political economies.
Brazil is useful for a different reason. Brazil was expected to add roughly 13 GW of solar in 2025, with distributed generation doing a large share of the work. That matters because customer-side solar can become the main event, not a decorative footnote to utility-scale projects. But Brazil has a clearer policy and reporting structure for distributed solar than most African markets do.
Chile gives us another lesson. Build enough solar and the next problem is not whether solar works. It is how to handle cheap daytime electricity, curtailment, transmission, and storage. In much of Africa, that stage is still ahead. The immediate storage value is more likely to be reliability, diesel displacement, and weak-grid resilience than classic solar curtailment management.
The African pathway is likely to be different from all three. It is more fragmented, more commercial, more Chinese-supplied, more behind-the-meter, more diesel-displacing, more mining-relevant, more mini-grid-heavy, and more annoying for official statisticians. That does not make it less real. It may make it easier to underestimate.
Egypt and Morocco are showing the grid-scale solar-plus-storage version. South Africa is showing the private industrial and constrained-grid version. Nigeria is showing the weak-grid, diesel-displacement, and mini-grid version. Zambia is showing the hydro-drought hedge version. The DRC is showing the mining-power version. Ghana and Botswana are showing industrial and early utility-scale versions. Chad and parts of the Sahel are showing access and small-base growth. Same technology family. Different economic jobs.
For readers who want the deeper professional analysis, I have published the full pathway review on my new professional Substack, Michael Barnard’s TFIE Strategy Briefing. That version includes the project inventory, non-solar renewables denominator check, reference-class comparison with India, Brazil, Chile, and Pakistan, update triggers for 2026, and the verdict summary I will use to track whether Africa’s solar story is showing up as official capacity, physical panel absorption, or some messy combination of both. If you enjoy heavier content, that’s where I’ll be publishing it, so hop over and subscribe. If you read me professionally, including if you have been using me as free due diligence, there’s a modest paywall for the deeper stuff now, but there will continue to be a regular drumbeat of free content, and all deep analysis will include a clear gloss.
The short public version is this: 20 GW of official African solar additions in 2026 looks unlikely. Around 20 GW of physical solar module absorption across the real economy is plausible. That distinction matters because official capacity tables are lagging indicators in weak-grid and distributed markets. Hardware flows, inverter and battery imports, diesel displacement, mining power contracts, mini-grid deployment, and commercial and industrial projects may be better early indicators.
The boom may not be missing. It may just be in the wrong column. If Africa’s solar story surprises people in 2026, it will not be because there was no data. It will be because too many people were looking only at official capacity tables while the hardware was already moving.
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Michael Barnard is Chief Strategist at TFIE Strategy and publisher of Michael Barnard’s TFIE Strategy Briefing at briefing.tfie.io. He works with investors, infrastructure strategists, NGOs, startups, policymakers, and public-interest organizations on reality-based decarbonization strategy, investment-thesis testing, technology diligence, 2030-2050 transition roadmaps, reports, keynotes, and strategic reality checks. His work tests energy, industry, transportation, infrastructure, and climate-tech pathways against physics, economics, operating evidence, denominators, comparators, and time. Michael’s analysis spans grids, storage, electrification, hydrogen, maritime and aviation fuels, critical minerals, China’s clean-tech scale, industrial decarbonization, geothermal, nuclear and SMR claims, and odd technoeconomic questions such as seabed mining and sulfur supply. Across those topics, his focus is consistent: separating real transition progress from pilots, subsidies, announcements, orderbooks, and narrative momentum. At Michael Barnard’s TFIE Strategy Briefing, free posts carry the public argument, while paid subscribers get the professional layer: Transition Pathway Scorecards, evidence notes, denominator checks, update triggers, reports, and decision-grade context for people working around the energy transition.
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