Chinese clean energy technology manufacturer JinkoSolar has launched Tiger Neo 3.0 in Australia, celebrates 1 GW delivery milestone and has signed multiple solar-plus-storage sgreements.
Image: JinkoSolar
China-headquartered solar and energy storage manufacturer JinkoSolar made an appearance at All Energy Australia 2025, launching its next-generation Tiger Neo 3.0 48-cell module specifically designed for the Australian market, along with innovative products including the SunGiga 261 kWh liquid-cooled energy storage system.
The Tiger Neo 3.0 employs 27% efficient, next generation TOPCon cells, delivering 670 W output at 24.8% module efficiency. In cloudy or dawn/dusk low irradiance conditions, the TOPCon modueles demonstrate superior performance with power generation increasing by 2.26-2.49%.

JinkoSolar’s Tiger Neo 3.0 series drew strong interest for its outstanding power generation performance. The 48-cell version has been specially optimised for distributed rooftop applications in Australia, delivering higher module efficiency, superior performance in low-light conditions, and significantly reduced levelised cost of energy (LCOE).
Against the backdrop of evolving electricity market dynamics and notable peak-to-off-peak price differentials in Australia, Tiger Neo 3.0’s enhanced low-light performance effectively extends daily power generation hours, delivering greater value to commercial, industrial, and residential users.

Milestone: 1 GW module delivery with Blue Sun Group
During the event, JinkoSolar and its long-term strategic partner Queensland-headquartere Blue Sun Group marked a major achievement—the successful delivery of over 1 GW of JinkoSolar modules in the Australian market within just three years.
This milestone reflects the close collaboration and shared commitment of both companies to advancing Australia’s clean energy transition.
As a leading distributor in Australia’s PV sector for the past two decades, Blue Sun Group has been dedicated to delivering high-quality products and tailored renewable energy solutions.
The deep co-operation between the two parties—spanning joint branding, product promotion, and market strategy—has supported a wide range of residential, commercial, and utility-scale projects, providing solid support for Australia’s energy transformation.

New partnerships
JinkoSolar also entered into a new round of partnerships with several leading energy companies during the exhibition:
GoSolar Group, a leader in Australia’s solar industry, will join forces with JinkoSolar to deliver high-performance Tiger Neo 3.0 products, bringing reliable and cost-effective solar power to more communities across the continent.
JinkoSolar and Jinko ESS, together with Greentech, will combine advanced Tiger Neo 3.0 modules with the SunGiga energy storage system, providing cutting-edge all-in-one solar-plus-storage solutions to the Australian market and empowering the transition to clean energy.
Jinko ESS signed a Letter of Intent with Aggreko, a global leader in mobile and modular energy solutions, for a 250 MWh battery energy storage project. The collaboration aims to deliver flexible, reliable, and sustainable energy solutions to the global market.
These achievements at All Energy Australia 2025 fully demonstrate JinkoSolar’s strong technological capabilities in driving the global energy transition through innovation.
Moving forward, JinkoSolar will continue to work closely with partners worldwide, injecting sustained momentum into renewable energy development in Australia and beyond.
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“The Tiger Neo 3.0 employs 27% efficient, next generation TOPCon cells, delivering 670 W output at 24.8% module efficiency. In cloudy or dawn/dusk low irradiance conditions, the TOPCon modueles demonstrate superior performance with power generation increasing by 2.26-2.49%.”
But, what are its physical dimensions?
And, with the “specifically designed for the Australian market”, how many of these panels can fit in the small triangular faces of the many hip roofs that are present in Australia; thence, how many Watts per square meter of hip roofing, can these panels produce?
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Summary: Mexico’s industrial companies are increasingly adopting distributed solar generation as a strategic financial and operational tool to manage rising electricity demand driven by nearshoring, manufacturing expansion, and logistics growth. Fiscal incentives under Mexico’s Income Tax Law, particularly the 100% immediate deduction for renewable energy equipment, combined with flexible financing models, such as PPAs and leasing, are accelerating investment across sectors, including manufacturing, logistics, hospitality, retail, and food processing. The shift positions solar energy as a mechanism to stabilize energy costs, improve cash flow, and strengthen corporate competitiveness in Mexico’s energy-intensive industrial economy.
 
Mexico’s industrial sector is entering a period where energy strategy is becoming increasingly central to corporate competitiveness. As electricity demand grows due to manufacturing expansion, logistics infrastructure, and nearshoring activity, companies are searching for ways to control energy costs while maintaining operational stability. In this context, distributed solar generation has evolved from a sustainability initiative into a financial and strategic asset for businesses operating in Mexico.
For many years, industrial solar panels were primarily associated with environmental responsibility and corporate sustainability commitments. Today, however, companies are recognizing that solar systems also offer tangible financial advantages. Beyond reducing electricity bills, solar systems can deliver fiscal incentives, improve cash flow, and strengthen long-term financial planning.
One of the most important factors accelerating solar adoption in Mexico is the fiscal framework that supports renewable energy investments. These incentives allow companies to treat solar systems not only as infrastructure improvements but also as financial tools capable of optimizing tax strategies and improving return on investment.
Solar Systems as Strategic Productive Assets
From a fiscal perspective, one of the most attractive aspects of investing in solar energy in Mexico is the tax incentive established under Article 34, Section XIII of the Income Tax Law (ISR). This provision allows companies to deduct up to 100% of the investment in renewable energy equipment during the same fiscal year in which the asset is installed. By allowing immediate deduction, the tax framework accelerates capital recovery, improves project feasibility and significantly strengthens cash flow during the year of investment.
Beyond this fiscal advantage, photovoltaic systems also function as productive assets that generate electricity throughout their operational life. From an operational standpoint, companies can offset a significant portion of their energy consumption with internally generated power, reducing dependence on grid electricity and protecting themselves from potential electricity rate increases. In industries where energy consumption represents a major operational cost, this benefit can have a substantial impact on long-term financial performance.
In Mexico, sectors such as manufacturing, hospitality, logistics, food processing, and retail have been particularly active in adopting industrial solar energy solutions, as companies look for ways to stabilize energy costs and improve financial predictability.
Energy price volatility has historically been a concern for companies operating in Mexico. While electricity rates depend on several factors, including fuel costs, grid demand, and regulatory adjustments, solar projects offer businesses a degree of control over their energy supply. This stability allows companies to better forecast operating costs and develop more reliable financial projections.
Compatibility with Financial Models
Another factor supporting the expansion of solar energy systems in Mexico is the flexibility with which these projects can be financed. Companies have access to a variety of financial structures that allow them to adopt renewable energy without necessarily committing large upfront capital investments.
The most common models include:
Direct purchase of the solar system: In this model, the company acquires the photovoltaic system as a capital asset and benefits directly from both the energy savings and the available fiscal incentives.
Power Purchase Agreements (PPA): Under a PPA structure, a third-party developer installs and operates the solar system while the company pays only for the electricity generated. This allows organizations to access renewable energy without making an initial capital investment.
Leasing or structured financing models: Some financial arrangements resemble equipment leasing structures, enabling companies to distribute payments over time while still benefiting from the energy generated by the system.
These models can be particularly attractive for companies seeking to maintain liquidity while still benefiting from renewable energy infrastructure.
In addition, specialized financial institutions focused on sustainable infrastructure, often referred to as “green banks,” have begun to play an important role in supporting renewable energy investments. These institutions provide financing solutions specifically designed for energy transition projects. By combining technical design with financial structuring, companies can develop solar energy projects that align closely with their operational and financial objectives.
ROI, Corporate Competitiveness
One of the strongest drivers behind solar adoption in Mexico is the relatively short return on investment associated with photovoltaic systems. Depending on the energy consumption profile of the facility, electricity rate, and system size, many corporate solar projects achieve payback periods between two and five years. Once the system has recovered its initial cost, the company continues generating electricity at minimal cost for the remainder of the system’s lifespan.
Modern photovoltaic systems typically operate for more than 25 years and require relatively low maintenance compared with other industrial infrastructure. This long operational horizon allows companies to generate stable energy savings for decades.
Beyond financial returns, solar energy systems also contribute to broader corporate strategies. Many companies are now evaluated based on their environmental, social, and governance (ESG) performance. Renewable energy generation can play an important role in improving sustainability metrics and demonstrating commitment to environmental responsibility.
Furthermore, in an economy increasingly influenced by international investment and global supply chains, access to clean and reliable energy has become a competitive advantage. Companies capable of demonstrating stable and sustainable energy strategies may be better positioned to attract investors, partners, and international clients.
As Mexico continues to strengthen its role as a manufacturing hub, particularly through nearshoring trends, energy reliability and cost management will remain critical factors for industrial growth. In this context, fiscal incentives for renewable energy investments function as financial accelerators. While the tax benefits themselves are important, the true value lies in the combination of fiscal advantages, operational savings, and long-term strategic positioning.
For many companies operating in Mexico today, solar energy is no longer simply an environmental decision. It is increasingly becoming a financial strategy, one that can reduce costs, optimize tax planning, and strengthen competitiveness in an increasingly energy-intensive economy.
 

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Science and Technology, Solar energy
California has begun testing a solution that combines infrastructure, energy e climate In the same space. Instead of using only solid ground to install solar panels, the state began covering sections of irrigation canals with elevated structures to produce electricity and protect the water from the heat.
The proposal is noteworthy because it addresses two problems at once. On the one hand, water disappears faster when temperatures rise. On the other, there is increasing pressure for more clean electricity generation without occupying new areas in regions already contested by agriculture, cities, and the expansion of power plants.
At the heart of this bet is the Project Nexus, a pilot mounted on Central Valley, CaliforniaThe experiment moved from the planning stage to reality with the promise of demonstrating, in practice, whether the canals can become a useful source for energy production without losing sight of the water crisis that is putting pressure on the state.
Scientists are transforming humans into “centaurs” with new technology that attaches robotic legs to the body, reduces the weight of loads by half, and makes mythological fiction take shape in the real world.
For decades, no one searched for lithium there, until wastewater from oil wells in Arkansas revealed a reserve of 5,1 million tons that could drastically reduce the US’s dependence on one of the most critical minerals of the electrical age.
New quantum battery surprises by halving charging time when doubled in size, intriguing even experts.
Almost no one knows this, but all the water in Earth’s atmosphere, including clouds and vapor, would only form 2,5 cm of rain if it fell all at once; yet, that same volume is recycled almost 40 times a year in a global cycle of over 500 km³ that sustains the planet’s climate.
The logic behind the project is straightforward. The panels are suspended above the water, allowing the canal to continue functioning while the structure generates electricity. At the same time, the shade reduces some of the direct sun exposure, which can decrease water loss through evaporation along the route.
This solution gained traction because it leverages an existing network. Instead of opening new areas, removing vegetation, or competing for space with other activities, the model attempts to give a secondary function to an already established public infrastructure. In a state that grapples with droughts, extreme heat, and ambitious climate goals, this detail is very important.
The project was also designed to observe effects that go beyond electricity generation. The expectation is that the covering will help control the excessive growth of aquatic plants, reduce some maintenance, and improve operating conditions in sections that were previously fully exposed to the sun.
The pilot was deployed in two excerpts The channel has different characteristics, precisely to test the solution’s performance in real-world situations. One location received a structure over a smaller span. The other was designed for a wider section, allowing for comparison of assembly, operation, and maintenance in distinct scenarios.
The project received approximately $20M monthly with state support and designed to deliver more than 1,6 MW renewable energy generation. In one of the areas, the proposal also included energy storage with iron flux batteries 75 kW, a feature that helps to show how the electricity produced in the canal can be better integrated into the system.
Second canary media, journalistic website specializing in energy transition.The installation was fully completed at the end of August 2025, after assembly and commissioning phases throughout the construction process. This gives the project a weight that goes beyond the symbolic image. It ceased to be a concept and began to operate on real water, with a real structure and real performance goals.
The great promise of canal coverage lies not only in electricity. The most sensitive point is the possibility of reducing water losses in a region that heavily depends on irrigation systems. During periods of intense heat, evaporation erodes significant volumes along the route, especially in open and extensive networks.
By creating shade over the canal, the panels act as a kind of partial barrier against this invisible loss. It’s not about eliminating the problem entirely, but about reducing waste that weighs more heavily when the weather worsens and water availability becomes more unstable. In a state where water and energy are already under pressure, this changes the equation.
There is also an indirect effect that helps explain the interest in the project. The presence of water under the panels can contribute to a slightly cooler microclimate, which tends to benefit the performance of the solar panels. In practice, the same structure that protects the water can also help improve the energy efficiency of the system.
Enthusiasm surrounding the topic grew after researchers modeled what would happen if a much larger portion of California’s public canal network received solar coverage. In this expanded scenario, the projection indicated savings of approximately… 63 billion gallons of water per yearin addition to a potential capacity close to 13 GW of solar energy.
These numbers help explain why the topic has gained traction outside of academia. The combination of preserved water resources with clean electricity generation creates a powerful narrative at a time when governments are seeking smarter solutions for infrastructure, climate adaptation, and emissions reduction.
But there is a crucial difference between projection and operational reality. The state figures are estimates of a much larger scenario, not the result already proven by the pilot program. What is at stake now is measuring, based on the operation of the installed sections, how much water is actually saved, what the real electrical output is, and what the cost of expanding the model will be.
The fact that the idea is promising doesn’t mean expansion will be automatic. Covering canals requires robust structures, constant maintenance, adaptation to different widths, and precise cost assessment per megawatt installed. In infrastructure projects, the most difficult stage almost always begins after the inauguration.
It will also be necessary to verify how the model behaves in larger networks, in more complex segments, and in areas with distinct operational requirements. A successful pilot paves the way, but does not eliminate questions about standardization, funding, and speed of deployment at a relevant scale.
Nevertheless, California has put forward a solution that few places have managed to test in a concrete way. By transforming canals into energy corridors, the state is attempting to respond with its own infrastructure to a crisis that is already putting pressure on water supply, agriculture, and electricity demand simultaneously.
The immediate impact may not be in the current volume of energy generated, but in what this experiment represents for the future. If the results confirm some of what is expected, solar coverage of canals could cease to be a technical curiosity and become a strategic element in dry and hot regions.

I am an Argentinian journalist based in Rio de Janeiro, focusing on energy and geopolitics, as well as technology and military affairs. I produce analyses and reports with accessible language, data, context, and strategic vision on the movements that impact Brazil and the world. 📩 Contact: noelbudeguer@gmail.com

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By Larry Loughlarry@thewoodstockindependent.com Amid an uncertain legal landscape for new solar farms in McHenry County, two are under construction around Woodstock, and a third is the subject of a lawsuit […]
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According to the latest IndexBox report on the global Solar Cable Management market, the market enters 2026 with broader demand fundamentals, more disciplined procurement behavior, and a more regionally diversified supply architecture.
The global solar cable management market, encompassing critical components like cable ties, conduits, trays, and junction boxes, is entering a pivotal growth phase aligned with the unprecedented global expansion of solar photovoltaic (PV) capacity. This analysis, covering the period 2026-2035, projects a robust trajectory underpinned by the energy transition, technological standardization, and the scaling of both utility-scale and distributed solar generation. Demand is fundamentally linked to new PV installations and the repowering of aging arrays, making cable management a consistent, non-discretionary expenditure within solar balance-of-system costs. The market’s evolution will be shaped by material innovation for enhanced durability, modular designs for faster installation, and increasing integration with smart monitoring systems. While growth faces headwinds from raw material volatility and supply chain complexities, the overarching drivers of decarbonization policies, falling solar LCOE, and energy security concerns present a strong baseline for expansion. This report dissects the demand drivers, sectoral shifts, and competitive dynamics that will define the market landscape through 2035.
The baseline scenario for the solar cable management market from 2026 to 2035 is one of sustained, above-GDP growth, directly mirroring global solar PV deployment forecasts. Underpinned by continued policy support, corporate renewable procurement, and improving project economics, annual solar capacity additions are expected to maintain a strong pace. This directly translates into steady demand for cable management systems, which are required in virtually every installation, from residential rooftops to gigawatt-scale solar farms. The market will benefit from a dual demand stream: new greenfield projects and the growing need for replacement and upgrade components in the existing fleet, which ages and requires maintenance. Technological progression will focus on reducing installed costs through prefabrication and plug-and-play solutions, while materials science will address longevity challenges in extreme environments like floating solar and arid regions. Competition will intensify, pressuring margins but driving innovation. The baseline assumes no major global recessions derailing energy investment and a continued, albeit uneven, policy commitment to renewables worldwide, leading to a compound annual growth rate in the mid-to-high single digits through the forecast horizon.
Utility-scale solar farms, typically defined as installations over 5 MW, constitute the largest and most consistent demand segment for solar cable management. Current demand is driven by multi-gigawatt annual capacity additions globally, where each project requires thousands of kilometers of cable trays, conduits, and millions of clips and ties for array and combiner box wiring. Through 2035, this segment will evolve as project sizes increase and system voltages rise to reduce losses, necessitating higher-specification conduits and junction boxes. Demand-side indicators include national renewable auction volumes, utility integrated resource plans, and power purchase agreement (PPA) announcements. The mechanism is direct and volume-based: every new MW of utility-scale solar capacity procures a roughly proportional quantity of cable management hardware. Trends toward bifacial modules and trackers also influence layout and cable routing designs, requiring adaptable management solutions. The segment’s growth is less sensitive to consumer economics and more tied to policy targets, grid infrastructure development, and the competitiveness of solar versus other generation sources. Current trend: Dominant and Growing.
Major trends: Adoption of 1500V DC systems becoming standard, requiring compatible conduits and enclosures rated for higher voltages, Modular and pre-assembled cable tray systems to reduce on-site labor and accelerate construction timelines, Increased use of aluminum cable trays and supports for weight reduction and corrosion resistance in large farms, Integration of cable management with SCADA and monitoring systems for potential fault detection along cable runs, and Design for extreme environments: dust-proofing in arid regions, enhanced UV protection, and resilience to high winds.
Representative participants: First Solar, NextEra Energy Resources, EDF Renewables, Enel Green Power, ACWA Power, and Longi.
The C&I segment encompasses solar installations on warehouses, factories, retail parks, and office buildings, primarily driven by corporate sustainability goals and rising retail electricity prices. Current demand focuses on robust, code-compliant solutions for flat and metal roofs, often requiring specialized mounting clips and fire-rated conduit penetrations. Through 2035, demand will be fueled by the broadening adoption of solar by small and medium enterprises, the expansion of solar carport and canopy installations, and building-integrated photovoltaics (BIPV). Key demand indicators include corporate renewable energy targets (RE100), commercial electricity rate trends, and local net metering or feed-in-tariff policies. The demand mechanism involves both new construction integrating solar and retrofits on existing buildings. This segment values products that ensure quick installation to minimize business disruption, aesthetic integration, and long-term reliability with minimal maintenance, as access for repairs can be costly and disruptive. Current trend: Steady Expansion.
Major trends: Growth of solar carports and canopies, requiring overhead cable management integrated with the support structure, Increased use of plug-and-play wiring harnesses and combiner boxes to simplify and speed up installation, Demand for low-profile, aesthetically discreet cable management solutions, especially for visible rooftop areas, Rise of behind-the-meter solar-plus-storage systems, requiring integrated cable management for DC/AC wiring and battery connections, and Stricter enforcement of building and fire codes for rooftop electrical systems, mandating certified products.
Representative participants: Tesla, SunPower, Sunnova, REC Group, Trina Solar, and JinkoSolar.
The residential segment involves solar installations on single-family and multi-unit homes. Current demand is for cost-effective, easy-to-install kits that include cable clips, ties, conduit, and junction boxes tailored for various roof types (asphalt shingle, tile, metal). Demand is primarily driven by homeowner economics, electricity prices, and available incentives. Looking to 2035, growth will be supported by continued policy incentives, rising electrification of home heating and transport (increasing household electricity demand), and the proliferation of solar-as-a-service models. Demand indicators include residential solar permit data, installer sales volumes, and consumer sentiment indices. The mechanism is high-volume but lower per-unit value compared to utility-scale. This segment is highly sensitive to installation labor costs, driving demand for products that minimize on-roof time, such as adhesive-backed clips and pre-formed conduit bends. Product durability remains critical to avoid costly call-backs for repairs over the system’s 25+ year life. Current trend: Mature Growth.
Major trends: Standardization of installation kits by major installers to streamline procurement and training, Growing use of microinverters and DC optimizers, which change cable routing patterns and junction box requirements, Increased focus on wildlife protection (e.g., rodent-resistant conduit) and aesthetic solutions to hide conduit runs, Integration with home energy management systems, potentially requiring data conduit alongside power cables, and Demand for retrofit solutions for older solar arrays needing cable management upgrades or replacements.
Representative participants: Sunrun, Vivint Solar, Enphase Energy, SolarEdge, Panasonic, and LG Electronics.
Floating photovoltaic (FPV) systems, deployed on reservoirs, lakes, and ponds, represent a rapidly growing niche with unique cable management challenges. Current demand centers on highly specialized components resistant to constant moisture, humidity, UV reflection from water, and potential mechanical stress from wave action. Products include waterproof junction boxes, corrosion-resistant cable trays, and floating conduit systems. Through 2035, this segment is forecast to grow at an above-market rate as land constraints drive adoption, particularly in Asia and Europe. Demand indicators include announcements of large FPV tenders, water body leasing agreements, and technological advancements in floating structures. The demand mechanism is project-specific and requires close collaboration between cable management suppliers and FPV platform engineers. Products must undergo rigorous testing for long-term immersion and environmental stress, creating a higher value-per-unit market with significant barriers to entry based on certification and proven performance. Current trend: High-Growth Niche.
Major trends: Development of integrated cable flotation systems that route cables along the floating platform itself, Use of submersible connectors and hermetically sealed enclosures to prevent water ingress, Materials innovation focusing on marine-grade stainless steel, specialized polymers, and anti-biofouling coatings, Standardization efforts for electrical components in FPV to reduce project-specific engineering costs, and Increasing project scale moving from megawatt to multi-hundred-megawatt installations, driving volume demand.
Representative participants: Ciel & Terre International, Swimsol, Ocean Sun, BayWa r.e, Scatec, and Kyocera.
This segment includes off-grid solar for remote communities, telecommunications towers, agricultural pumps, and mobile applications like solar-powered vehicles, trailers, and portable kits. Current demand is for ruggedized, versatile cable management that can withstand vibration, dust, and wide temperature swings, often in environments with no easy access for maintenance. Products include strain relief glands, flexible conduit, and compact junction boxes. Through 2035, demand will be supported by rural electrification programs, the expansion of IoT and telecom infrastructure in remote areas, and the nascent market for solar-integrated electric vehicles and transportation. Key demand indicators include funding for off-grid electrification projects, sales of solar home system kits, and development of solar-powered mobility. The demand mechanism is fragmented but persistent, often involving smaller batch orders for highly durable components. Reliability is paramount, as system failure in remote locations can have significant operational consequences, justifying a focus on quality over lowest cost. Current trend: Steady Specialized Demand.
Major trends: Miniaturization of components for portable and vehicle-integrated solar systems, Use of quick-disconnect and waterproof connectors for easy deployment and reconfiguration, Demand for all-in-one enclosures that house connectors, fusing, and monitoring in a single, sealed unit, Growth in solar-powered agriculture (agrivoltaics and irrigation) requiring cable management resistant to chemicals and physical impact, and Increasing standardization in the off-grid solar kit market, leading to common cable management specifications.
Representative participants: Schneider Electric, ABB, OutBack Power, Victron Energy, Goal Zero, and Jackery.
Interactive table based on the Store Companies dataset for this report.
Asia-Pacific will remain the undisputed demand leader, driven by China’s colossal solar deployment targets, India’s ambitious renewable goals, and rapid growth in Southeast Asia and Australia. The region’s massive manufacturing base for both solar panels and balance-of-system components creates a integrated, cost-competitive supply ecosystem. Demand is heavily skewed towards utility-scale projects, but residential and C&I segments are growing swiftly. Policy consistency and grid integration capabilities are the key variables influencing the pace of growth. Direction: Dominant and Expanding.
North America, led by the U.S., exhibits robust demand supported by the Inflation Reduction Act’s long-term tax incentives, state-level renewable portfolio standards, and strong corporate procurement. The market is diverse, with significant activity in utility-scale, community solar, and residential segments. Technological innovation and high labor costs drive demand for premium, labor-saving cable management solutions. Trade policies and domestic manufacturing initiatives may gradually reshape the supply chain landscape through the forecast period. Direction: Strong Growth.
European demand is underpinned by the EU’s Green Deal and REPowerEU plan, aiming to accelerate solar deployment for energy security and decarbonization. Growth is strong across Southern, Western, and Central Europe. The market is characterized by high quality and safety standards, driving demand for certified, durable products. The C&I and residential segments are particularly active, with growing interest in BIPV and agrivoltaics. Regulatory harmonization and permitting reforms will be critical to maintaining growth momentum. Direction: Steady, Policy-Driven.
This region presents a high-growth frontier, led by massive utility-scale projects in the Gulf Cooperation Council (GCC) states and significant off-grid and mini-grid potential in Sub-Saharan Africa. Demand is bifurcated: large-scale tenders in the Middle East require products for extreme heat and dust, while African markets need cost-effective, durable solutions for both utility-scale and decentralized systems. Project financing and political stability are key determinants of the realized growth rate through 2035. Direction: Emerging High-Potential.
Latin America shows steady growth potential, with Brazil, Chile, and Mexico as primary markets. Demand is driven by competitive solar resources, auction systems, and growing C&I adoption. The market faces challenges related to currency volatility, grid infrastructure limitations, and sometimes inconsistent policy support. However, the fundamental economics of solar power and increasing private sector investment are expected to support a gradual expansion of the cable management market, particularly for utility-scale and commercial projects. Direction: Moderate but Increasing.
In the baseline scenario, IndexBox estimates a 8.2% compound annual growth rate for the global solar cable management market over 2026-2035, bringing the market index to roughly 218 by 2035 (2025=100).
Note: indexed curves are used to compare medium-term scenario trajectories when full absolute volumes are not publicly disclosed.
For full methodological details and benchmark tables, see the latest IndexBox Solar Cable Management market report.
This report provides an in-depth analysis of the Solar Cable Management market in the World, including market size, structure, key trends, and forecast. The study highlights demand drivers, supply constraints, and competitive dynamics across the value chain.
The analysis is designed for manufacturers, distributors, investors, and advisors who require a consistent, data-driven view of market dynamics and a transparent analytical definition of the product scope.
This report covers the market for solar cable management systems, which are specialized components designed to organize, secure, protect, and route electrical wiring within photovoltaic (PV) installations. These products are critical for ensuring system safety, reliability, longevity, and compliance with electrical codes by managing cables from solar panels to inverters and other balance-of-system components.
Solar cable management products are classified under various international trade codes, primarily within the Harmonized System (HS) chapters for electrical machinery and plastics. Given their composite nature—combining insulating, protective, and structural functions—they span classifications for insulated wire, electrical conduits, plastic fittings, and connection devices used in electrical circuits.
World
The analysis is built on a multi-source framework that combines official statistics, trade records, company disclosures, and expert validation. Data are standardized, reconciled, and cross-checked to ensure consistency across time series.
All data are normalized to a common product definition and mapped to a consistent set of codes. This ensures that comparisons across time are aligned and actionable.
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Harnessing the Sun: How Solar and Battery Solutions are Transforming Energy in Australia
Wingfield, Aruba – March 15, 2026 / Ozora Electrical and Renewable Energy /
Australia is experiencing a remarkable transformation in its energy landscape, driven by the rapid adoption of solar and battery installation. With projections indicating that home batteries will reach a staggering 4.7 GWh by 2025/26 and rooftop solar systems expected to supply over 50% of the grid’s demand, the country is on the brink of a solar revolution. Federal rebates are further incentivizing this shift, making solar energy more accessible to homeowners and businesses alike.
Ozora Energy stands at the forefront of this movement, leveraging over a decade of expertise in solar photovoltaic (PV) systems, battery storage solutions, and electric vehicle (EV) charging infrastructure. Licensed to operate in South Australia, Victoria, and New South Wales, Ozora Energy is committed to providing high-quality services that empower customers to take control of their energy consumption. With a lifetime warranty on their installations and an impressive 5.0 out of 5 customer review rating, Ozora Energy has established itself as a trusted partner in the solar and battery installation sector.
The benefits of solar and battery systems are substantial. Homeowners and businesses can achieve energy independence, significantly reduce their energy bills, and protect themselves against power outages. The return on investment (ROI) for these systems typically ranges from five to seven years, making them a financially sound choice for many Australians. As the summer months approach, with their accompanying heatwaves and increased energy demands, the timing for solar and battery solutions could not be better.
Ozora Energy’s commitment to customer satisfaction is evident in the stories shared by their clients. A Sydney homeowner recently reported slashing their energy bills by more than half after installing a solar PV system combined with battery storage. This transformation not only provided financial relief but also enhanced their energy independence, allowing them to rely less on the grid. In Adelaide, a customer praised Ozora Energy for their “five-star service,” highlighting the professionalism and expertise of the team throughout the installation process. Meanwhile, a business owner in Mildura experienced a quick ROI, demonstrating how commercial installations can also yield significant savings and operational benefits.
The statistics surrounding Australia’s solar energy capabilities are impressive. By 2026, it is anticipated that the country will have 15 GWh of battery storage capacity, with solar energy peaks reaching 4,407 MW. These figures underscore the growing importance of renewable energy sources in Australia’s overall energy strategy. As more Australians embrace solar and battery technology, the potential for a more sustainable and resilient energy future becomes increasingly attainable.
Ozora Energy’s expertise extends beyond just solar PV and battery storage. The company is also well-versed in EV charging solutions, catering to the growing number of Australians making the switch to electric vehicles. By integrating EV charging infrastructure with solar and battery systems, customers can maximize their energy savings and further reduce their reliance on traditional power sources.
The local presence of Ozora Energy in Adelaide, Sydney, and Mildura ensures that customers receive personalized service tailored to their specific needs. The company’s team of residential and commercial electricians is dedicated to delivering high-quality installations and ongoing support, making the transition to solar energy as seamless as possible.
As Australia continues to grapple with rising energy costs and the threat of blackouts, the importance of investing in solar and battery solutions cannot be overstated. The combination of federal incentives, technological advancements, and a growing awareness of the benefits of renewable energy is driving a significant shift in how Australians approach their energy consumption. By choosing Ozora Energy for solar and battery installation, customers are not only making a smart financial decision but also contributing to a more sustainable future for the entire country.
In conclusion, the solar and battery revolution in Australia is well underway, with Ozora Energy leading the charge. With their extensive experience, commitment to quality, and focus on customer satisfaction, they are helping Australians harness the power of the sun to achieve energy independence and protect against rising energy costs. As the summer sun shines down, now is the perfect time for homeowners and businesses to explore the benefits of solar and battery solutions.
Learn more on https://www.ozora.com.au
Contact Information:
Ozora Electrical and Renewable Energy

13 Fifth Street
Wingfield, SA 5013
Aruba
James Watt
1300 069 672
https://ozora.com.au

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European Energy (EE), a Denmark-based renewable energy developer, has recently commissioned the 108 MW Lancaster PV farm in Australia. This facility in Victoria is equipped with approximately 170,000 solar panels and will provide power to Apple under a long-term PPA. According to EE, the asset has added operating capacity to its Australian portfolio, where the development pipeline stands at approximately 10 GW. The Australian pipeline includes solar, onshore wind, and battery storage projects. EE said Winton North is under construction, while Mulwala Solar Farm has completed construction and is in commissioning. Both assets are located within 90 minutes of Lancaster.

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French renewables developer TE H2 has filed a government application seeking approval for a 2.7 GW solar farm and 6 GWh battery energy storage project to be built in Australia’s Northern Territory.
Image: TotalEnergies
From pv magazine Australia
TE H2, a joint venture between French oil giant TotalEnergies and Paris-based renewables producer Eren Groupe, has submitted plans for one of Australia’s largest solar and battery energy storage projects for review under the Environment Protection and Biodiversity Conservation (EPBC) Act.
The federal government-administered EPBC review process aims to protect nationally threatened species and ecological communities.
The AUD 2.8 billion ($1.9 billion) Wak Wak project, proposed for a 3,400-hectare site near Humpty Doo, about 48 km south of Darwin, is to include a 2.7 GW solar farm that would “allow for an optimized, year-round energy supply to the potential electricity off-takers.”
In documents referred for assessment under the federal EPBC Act, TE H2 said the concept design also includes 6 GWh of battery energy storage to “firm up the renewable energy supplied and to balance solar power generation with electricity consumption at downstream facilities, provide local network stability services, and serve as a backup to ensure a secure facility shutdown when needed.”
TE H2 said while “the project is currently at concept design stage,” the objective of the proposal is to generate and store renewable solar energy for both existing industry in the greater Darwin region, and potentially, for the generation of renewable green hydrogen.
“The ultimate end use of the solar energy is as a critical input to produce firm renewables energy supply to existing industrial end users on Middle Arm initially and to power green hydrogen production at the Middle Arm Precinct at a later stage,” TE H2 said.
EPBC referral documents say renewable energy generated at the Wak Wak facility will be sent via a planned high-voltage overhead transmission line to Middle Arm where TE H2 has the Darwin H2 Hub in development, and potentially connect into the Darwin Katherine grid.
TE H2’s proposed Darwin H2 Hub is to include a 1 GW electrolyzer capable of producing more than 80,000 tonnes of green hydrogen per annum for national and international markets.
Construction of the Wak Wak solar and battery facility is expected to commence in 2027, pending project approvals, It is likely the solar farm will be developed in stages with the first phase expected to be in the vicinity of up to 900 MW.
TE H2 said power for construction will include a combination of temporary solar and battery storage on site, likely supplemented by diesel generators during the establishment and early works phase.
It is expected the project will generate up to 900 jobs during the construction phase.
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Govt mandates domestic sourcing of solar wafers for manufacturers  Business Standard
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Deep-tech startup Hbaromega has found exceptional compatibility of its advanced light beam induced current (LBIC) characterization technology for back contact (BC) solar cells with encouraging initial results. It said LBIC enables high-resolution analysis of carrier transport and defect localization in BC architectures.
High-resolution LBIC scan of a BC cell
HbarOmega
Hbaromega(ℏω), a deep-tech startup specializing in photovoltaic quality control and advanced characterization technologies, has announced encouraging results of adapting its advanced light beam induced current (LBIC) characterization for back contact (BC) solar cells. It said initial studies indicate that the method can deliver significantly deeper diagnostic insights than conventional characterization approaches, offering a more precise understanding of the performance of complex BC architectures.
BC technology has emerged as one of the most prominent trends in today’s PV landscape. With TOPCon already established as the industry’s workhorse technology, many leading PV manufacturers are actively evaluating BC architectures, while some have already launched commercial production at multi-gigawatt scale. Nevertheless, the technology remains subject to extensive optimization.
In this context, LBIC characterization offers a particularly powerful diagnostic tool. In this technique, a focused laser beam scans across the solar cell surface while the generated photocurrent is recorded, producing a high-resolution map of carrier collection efficiency. This approach allows the identification of performance-limiting defects such as microcracks, recombination-active regions, and transport non-uniformities. Unlike luminescence-based techniques, LBIC directly measures collected current under short-circuit conditions, providing a direct indicator of carrier transport efficiency within photovoltaic devices.
BC cells present unique diagnostic challenges due to their architecture, particularly the lateral p-n junction design. Explaining this aspect, Prashant Kumar, CTO of Hbaromega, said: “In BC cells, charge carriers must travel vertically through the bulk of the device and then laterally toward the interdigitated rear contacts. The spacing between these fingers typically ranges from about 0.5 to 2 mm. Carriers generated midway between adjacent contacts may therefore need to diffuse laterally over distances of roughly 250 to 1000 µm before being collected. As a result, the effective diffusion length requirements in BC cells often exceed 1 mm. Under these conditions, device performance becomes strongly transport-limited rather than primarily recombination-limited.”
These characteristics also pose challenges for conventional characterization methods such as electroluminescence (EL) and photoluminescence (PL). According to Prof. K. S. Narayan, Founder Director, Hbaromega, the key advantage of LBIC lies in the precision of its probing mechanism. “In EL and PL, the semiconductor itself acts as the light source, and the emitted light scatters within the device, reducing spatial resolution. LBIC, in contrast, employs an external, highly focused light spot that directly probes the sample. This eliminates internal scattering and significantly improves measurement precision,” he said.
As a result, LBIC can produce sharper signal transitions between grid regions and the cell body, enabling the detection of fine structural variations and localized defects that emission-based methods often miss. The technique can identify rear-contact recombination, recombination between p+ and n+ fingers, bulk lifetime non-uniformities, and lateral transport bottlenecks. By correlating spatial LBIC responses with contact geometries and probe wavelengths, manufacturers can also quantify contact misalignment effects and process-induced degradation zones. This capability allows a comprehensive evaluation of both vertical and lateral transport constraints, helping bridge the gap between laboratory research and industrial-scale BC production.
Another important aspect of Hbaromega’s solution is its industrial applicability. Historically, LBIC has been limited by scanning speed, with full-area mapping of a standard M10 cell often requiring several hours depending on spatial resolution. With advances in high-speed beam positioning, fast data acquisition electronics, optimized scanning algorithms, and parallel signal processing, Hbaromega has developed high-speed LBIC systems capable of mapping full-area solar cells within seconds.
On the commercial front, the company currently offers two product platforms: PV Vision Pro, designed for solar cell characterization, and ModuleXpert, tailored for module-level diagnostics. In addition to their proprietary LBIC capabilities, both systems support EL and PL characterization, providing a comprehensive diagnostic toolkit for photovoltaic manufacturers.
Hbaromega is currently seeking industrial partnerships to further advance the deployment of its characterization technologies in next-generation solar cell manufacturing.
Hbaromega(ℏω), founded in 2019 at the Jawaharlal Nehru Centre for Advanced Scientific Research (JNCASR) in Bengaluru, focuses on developing advanced photovoltaic characterization technologies for research institutions and the solar manufacturing industry.
Through locally engineered instrumentation and physics-driven diagnostics, Hbaromega aims to provide high-performance characterization tools that support the evolving photovoltaic manufacturing ecosystem.
 
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India added 119 GW of solar module capacity and over 9 GW of cell capacity in 2025, bringing total capacities to about 210 GW and 27 GW, respectively, according to Mercom India. Growth was driven by strong project demand and policy support, although supply-demand alignment is expected later in 2026 as domestic cell production ramps up.
Emmvee’s solar cell production line
Image: Emmvee
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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A 620 MW solar project to be constructed in South Africa’s Free State has reached financial close. The milestone follows the signing of a more than 20-year multi-offtaker wheeling agreement with commercial and industrial clients. 
Image: Avi Waxman, Unsplash
South African independent power producer Anthem has announced financial close on its Notsi Solar PV project located in South Africa’s Free State.
With a planned capacity of 620 MW (475 MWac), it is billed as the largest solar project in the country to date.
The Notsi project is set to cover more than 1,000 hectares and feature over 860,000 solar panels. Once operational, it will generate approximately 1.5 TWh annually. A statement published by Anthem says it will supply energy over the national grid to the commercial and industrial sectors for over 20 years, via a multi-offtaker wheeling model in place with financial services provider Discovery Limited and green energy supplier NOA.
“By supplying renewable energy to corporate and commercial offtakers, the Notsi project supports the growing aggregator market, enables corporate decarbonization and supports South Africa’s transition to lower‑carbon, more sustainable energy consumption,” commented Anthem Chief Commercial Officer, Mike Wickins.
The Notsi project is being debt financed by a consortium including Standard Bank Group, Nedbank Corporate and Investment Banking, Absa Group, Vantage Capital and Third Way Investment Partners.
Anthem is responsible for all asset management in construction and operations and will assume operations and maintenance responsibilities from year three of operations onwards. A joint venture company belonging to two Chinese developers, China Energy Engineering Corporation and Northwest Electric Power Design Institute, has been awarded the engineering, procurement and construction contract.
According to details on its website, Anthem has an asset portfolio of over 2 GW, including over 1 GW of assets delivered through South Africa’s renewable procurement program, and an additional project pipeline in excess of 11 GW.
Last month, South African independent power producer SOLA Group reached financial close on its Naos‑1 hybrid solar-plus-storage project, touted as the first of its kind in the country purpose-built for wheeling power to private end-users across the grid.
South Africa’s cumulative solar capacity now stands in excess of 10 GW, after deploying 1.6 GW last year.
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Investment opportunities for utility-scale solar and wind areas: Angola zoning assessment  IRENA – International Renewable Energy Agency
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Danish independent power producer (IPP) European Energy has inaugurated the 108MW Lancaster Solar Farm in northern Victoria.
The IPP has signed what it called a “long-term” power purchase agreement (PPA) with technology giant Apple to sell power generated at the project, but did not provide further details on the length of the deal.
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As part of the deal, the company signed a memorandum of understanding (MoU) with the Yorta Yorta Nation Aboriginal Corporation to cooperate on future renewable energy projects across land belonging to the Yorta Yorta group in Victoria.
The project inauguration, and the signing of the MoU with the Yorta Yorta people, coincided with the Danish royal couple’s state visit to Australia; Danish King Frederik X, Danish Queen Mary and Australian Minister of Energy Chris Bowen were present for the MoU signing. European Energy said this MoU would result in initiatives to support “workforce participation, Indigenous business engagement and initiatives aligned with the self-determined priorities of the Yorta Yorta people”.
“This agreement recognises the Yorta Yorta people as Traditional Owners and sets out how we will work together to protect culture, respect Country and ensure our people share in the benefits of renewable energy development,” said chair of the Yorta Yorta National Aboriginal Corporation, Trent Nelson.
The news follows European Energy securing approval for a 1.1GW solar project in Queensland, as the company looks to expand its Australian presence. The company currently has a development pipeline of 10GW of solar, wind and battery energy storage systems (BESS) in Australia, and is at the late stage of development for both the 131MW Winton North solar project in Victoria and the 31MW Mulwala solar facility in New South Wales.

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India added 119GW of solar module and over 9GW of solar cell manufacturing capacity in 2025, according to Mercom’s latest report. 
According to the State of Solar PV Manufacturing in India 2026 report, India’s cumulative module manufacturing capacity stood at approximately 210GW, while cell manufacturing capacity reached around 27GW, in December 2025.  
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Under the government’s Approved List of Models and Manufacturers (ALMM) List-I, module capacity was 173.1GW, with cell capacity under ALMM List-II nearly 26.5GW. The top ten Indian manufacturers accounted for 44% of module and 99.5% of cell production capacity. 
This surge was driven by the Government of India’s solar initiatives, including the PM Surya Ghar program and the ALMM List-II domestic cell mandate introduced last year. These policies boosted demand for both utility-scale solar projects in the pipeline and rooftop solar installations.   
Mercom said that approximately 70% of installed module manufacturing capacity was based on tunnel oxide passivated contact (TOPCon) technology, followed by monocrystalline at over 25%. Polycrystalline and thin-film technologies accounted for around 2% each, while heterojunction (HJT) module capacity, at about 1%, was included for the first time. The remainder comprised a combination of HJT and TOPCon. 
For cells, monocrystalline technology accounted for more than 57% of production capacity, followed by TOPCon (over 39%) and polycrystalline (3.5%). 
Furthermore, the Mercom report highlighted that Gujarat led module manufacturing with a 45% share, followed by Rajasthan (10%) and Tamil Nadu (7%). Gujarat also dominated cell production with approximately 45%, with Tamil Nadu (16%) and Karnataka (13%) trailing.
Domestic manufacturers exported around 5GW of modules and 192MW of cells in 2025. The US accounted for 96.8% of module exports, while 57% of cell exports went to the UAE. 
Solar PV module exports in Q4 2025 reached US$98.96 million, while imports of modules totalling US$216.25 million, with Vietnam (33%), China (32%), and Malaysia (31%) as leading suppliers. Solar cell imports rose 31% quarter-on-quarter to US$892.15 million, dominated by China at 67% of total imports. 
Earlier this month, JMK Research’s Q4 2025 India RE Update report noted that India’s solar module capacity grew nearly 14-fold between 2020 and 2025, reaching 200GW, of which 145GW was enlisted under ALMM.
India is projected to add 42.5GW of new solar capacity in 2026, including 32.5GW from utility-scale projects, 8.5GW from rooftop solar, and 1.5GW from off-grid installations. During Q4 2025, the country added 6.2GW of utility-scale solar, a 23% decline from the previous quarter, while rooftop installations reached 2.1GW, down 22% quarter-on-quarter. 

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In a major policy shift aimed at curbing import dependence, the government on Wednesday mandated that all solar projects use locally manufactured ingots and wafers from June 1, 2028, extending domestic sourcing rules to the most import-dependent segment of the solar supply chain.
The move, notified by the Ministry of New and Renewable Energy (MNRE), expands the Approved List of Models and Manufacturers (ALMM) framework beyond modules and cells to upstream components, where India remains heavily reliant on imports, largely from China.
Solar panels are made up of modules that contain cells. Cell manufacturing depends on ingots, which in turn require wafers. India currently has around 2 GW of ingot and wafer manufacturing capacity, even as solar deployment continues to accelerate. The new mandate will apply across utility-scale, open access and net-metering projects, with future bids required to comply.
To avoid supply disruption, the government will notify eligible manufacturers only after at least three independent players with a combined capacity of 15 GW are operational. Companies will also be required to have integrated manufacturing capability across ingots and wafers, pushing the sector towards scale and vertical integration.

Union Minister for New and Renewable Energy Pralhad Joshi said the decision aims to deepen domestic manufacturing. “The move will boost domestic production, enhance supply chain resilience, reduce import dependence, and ensure higher quality standards across the solar value chain,” he said.
Industry executives said the policy signals a decisive shift towards upstream localisation. Srivatsan Iyer, Global CEO of Hero Future Energies, said the move strengthens the ecosystem but requires careful execution. “This is a significant step towards strengthening India’s renewable ecosystem… however, capacity build-up and ecosystem readiness will be critical,” he said.
Industry executives said the policy signals a decisive shift towards upstream localisation. Srivatsan Iyer, Global CEO of Hero Future Energies, said the move strengthens the ecosystem but requires careful execution. “This is a significant step towards strengthening India’s renewable ecosystem…however, capacity build-up and ecosystem readiness will be critical,” he said.
Prashant Mathur, CEO of Saatvik Green Energy, said the decision reinforces India’s intent to control its supply chain. “This is a bold affirmation that India is determined to own its solar supply chain, cut import dependencies, and generate high-quality manufacturing jobs at scale,” he said.
However, industry bodies flagged the scale of investment required. Subrahmanyam Pulipaka, CEO of NSEFI, said timely capacity creation will be key. “The successful implementation… is closely dependent on the timely creation and scaling of domestic ingot and wafer manufacturing capacity,” he said, calling for viability gap funding support.
The industry has proposed ₹20,000–25,000 crore in support to build 50 GW of upstream capacity, along with additional incentives for domestic equipment manufacturing.
The ALMM framework, introduced in 2019, has already driven downstream expansion. Since its rollout, domestic capacity has scaled up sharply, with module manufacturing rising from 8.2 GW in 2021 to 172 GW, while cell capacity has reached 27 GW within seven months, reflecting rapid industry expansion.
Mahindra & Mahindra has faced backlash for reintroducing their limited-edition BE 6 Batman Edition electric SUV. The second batch of 999 units sold out quickly, but original buyers criticized the move for devaluing exclusivity. In response, Mahindra has offered a buyback option to early customers, reflecting their focus on customer satisfaction.

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In the relentless pursuit of higher photovoltaic efficiencies, the integration of perovskite materials with silicon has emerged as a transformative approach, surmounting the inherent limitations of traditional solar cells. Recently, groundbreaking progress in triple-junction solar cells comprising perovskite and silicon has been reported, offering remarkable improvements in efficiency while addressing persistent challenges in device architecture and material stability. This advancement promises to redefine the landscape of solar technology by pushing the boundaries of power conversion efficiency beyond what dual-junction cells can offer.
Perovskite-silicon triple-junction photovoltaics represent a complex yet highly rewarding engineering feat. By stacking three sub-cells with distinct bandgaps, these devices harness a broader spectrum of sunlight more effectively than simpler architectures. However, the complexity introduced by this multilayer device structure leads to practical bottlenecks that have historically limited device performance. Two primary issues dominate the design challenges: first, the wide-bandgap perovskite top-cell suffers from reduced open-circuit voltage, undermining overall voltage output; second, the middle perovskite layer faces restricted photocurrent generation due to difficulties in fabricating thick, high-quality absorber layers that maintain structural and electronic integrity.
Addressing the voltage deficit in the wide-bandgap top-cell, researchers have innovated by incorporating a carefully selected non-volatile additive, 4-hydroxybenzylamine. This organic molecule exerts a profound influence on the crystallization dynamics of the perovskite layer, steering film formation towards preferential orientation. Such controlled crystallization not only enhances carrier transport pathways but also passivates defects that act as non-radiative recombination centers—pathways that waste photogenerated charges and reduce voltage. The result is a dramatic boost in open-circuit voltage, reaching values as high as 1.405 volts, a record performance metric for wide-bandgap perovskite top-cells.
Complementing this additive’s role, meticulous optimization of energy-level alignment within the device layers further mitigates voltage losses. By carefully tuning energy band offsets between the perovskite and charge transport layers, engineers realized improved charge extraction efficiency, minimizing recombination at interfaces. The synergy of material chemistry and electronic engineering culminates in a top-cell that not only delivers higher voltage but also manifests enhanced operational stability, a critical criterion for commercial viability of perovskite-based solar technologies.
While voltage enhancement is vital, maximizing the current output from the middle-cell is equally challenging yet essential for achieving commercially compelling efficiencies in triple-junction devices. The difficulty lies in depositing thick perovskite layers with narrow bandgaps that absorb a substantial fraction of the solar spectrum without compromising the electronic quality. To overcome this, a novel three-step deposition approach was developed. This strategy enables the growth of thick, low-bandgap perovskite films that retain exceptional microstructural integrity, avoiding issues like excessive grain boundaries or defect formations that traditionally degrade performance.
Maintaining the morphological and electronic quality of these thick absorbers is pivotal for efficient electron extraction. The refined deposition technique ensures that the perovskite layers exhibit uniform crystallinity and minimized trap state density, crucial for long carrier lifetimes and diffusion lengths. Consequently, the photocurrent generation in the middle-cell is significantly improved, translating into a more balanced current matching between the sub-cells, a prerequisite for high-performance tandem configurations.
Another ingenious aspect of the recent work is the integration of low-refractive-index silicon oxide (SiOx) nanoparticles strategically embedded in the front valleys of the textured silicon bottom-cell. This subtle optical engineering acts as a middle-reflector, exploiting photonic effects to enhance light trapping within the middle perovskite layer. By selectively reflecting longer-wavelength photons back into the intermediate absorber, these nanoparticles boost photon absorption and charge carrier generation without contributing additional parasitic absorption or scattering losses.
This sophisticated photon management approach enhances the overall light-harvesting capacity of the triple-junction stack, effectively utilizing incident solar radiation with minimal optical losses. The intimate interplay between nanoscale optical structuring and hybrid material interfaces signifies a new paradigm in multijunction solar cell design, where electronic and photonic optimizations are woven seamlessly to elevate device performance.
Critically, these two parallel advances—the voltage improvement in wide-bandgap perovskite top-cells and the photocurrent enhancement in narrow-bandgap middle-cells—were successfully integrated in practical, 1 cm² perovskite-perovskite-silicon triple-junction devices. The resulting solar cells achieved a certified power conversion efficiency of 30.02%, a milestone that firmly situates this technology at the forefront of photovoltaic research and commercial potential. Such efficiency gains represent a significant leap beyond the typical limits of silicon-based tandem cells, inching closer to the theoretical efficiency ceiling for multijunction devices.
Beyond raw performance, the reported devices exhibit promising stability characteristics under operational conditions, addressing one of the long-standing concerns hindering the adoption of perovskite materials. The role of 4-hydroxybenzylamine in defect passivation and film stabilization is critical here, ensuring that the device maintains performance integrity over extended periods. This stability is fundamental for transitioning these high-efficiency laboratory prototypes into reliable products fit for market deployment.
This breakthrough also underscores the importance of interdisciplinary approaches in photovoltaic research, blending chemistry, materials science, optical physics, and device engineering. The precisely orchestrated control over perovskite crystallization chemistry, deposition protocols, energy band alignments, and nanophotonic design exemplifies how holistic innovation can overcome entrenched material and device limitations.
Looking ahead, the roadmap for perovskite-silicon triple-junction solar cells is now enriched with practical design guidelines and scalable fabrication techniques demonstrated by this work. Future research will likely explore further improvements in long-term durability, manufacturability at scale, and integration into real-world photonic and energy systems. Moreover, the conceptual insights into additive-assisted crystallization and nanostructured photon management may extend to other optoelectronic applications beyond photovoltaics, such as photodetectors and light-emitting devices.
In conclusion, the confluence of advanced material additives, novel deposition methodologies, and sophisticated nanophotonic engineering presents a paradigm shift for next-generation solar technologies. The achievement of over 30% certified efficiency in triple-junction perovskite-perovskite-silicon cells offers a compelling vision for high-performance, cost-effective renewable energy solutions. As the global energy landscape demands cleaner and more efficient technologies, such innovations pave the way for perovskite-based multijunction photovoltaics to become a cornerstone of sustainable energy infrastructure in the coming decade.
Subject of Research: Perovskite-silicon triple-junction solar cells and advanced carrier/photon management strategies for enhanced photovoltaic efficiency.
Article Title: Triple-junction solar cells with improved carrier and photon management.
Article References:
Artuk, K., Turkay, D., Kuba, A., et al. Triple-junction solar cells with improved carrier and photon management. Nature (2026). https://doi.org/10.1038/s41586-026-10385-y
Image Credits: AI Generated
Tags: 4-hydroxybenzylamine additiveadvanced photovoltaic materialshigh efficiency solar cellsmultilayer solar cell architecturenext-generation solar technologyopen-circuit voltage enhancementperovskite-silicon photovoltaicsphotocurrent generation optimizationpower conversion efficiency improvementstable perovskite absorber layerstriple-junction solar cellswide-bandgap perovskite challenges
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RZOLV recycles silver from solar panel scraps | 2026-03-18 | Investing News  Stockhouse
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March 18, 2026e-Paper
The View From India Looking at World Affairs from the Indian perspective.
First Day First Show News and reviews from the world of cinema and streaming.
Today's Cache Your download of the top 5 technology stories of the day.
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March 18, 2026e-Paper
Published – March 18, 2026 08:05 pm IST – NEW DELHI
India has targetted adding 280 GW of solar capacity by 2030 and has installed about 132 GW as of November 2025.  | Photo Credit: KUMAR SS
In a bid to boost domestic manufacturing of solar ingots and wafers – the constituents of solar cells that are then fitted on solar panels – the Ministry for New and Renewable Energy (MNRE) has said that from June 2028, only ingots and wafers made in India would be eligible for domestic projects.
It did this by announcing the Approved List of Module Manufacturers (ALMM) List-III for Ingots and Wafers – a list of companies that make these components – on Wednesday. As of today, such an ALMM list exists for manufacturers of solar cells and modules. The Approved List of Models and Manufacturers (ALMM) is a compulsory registration regime by the  MNRE, first issued in 2019. Only ALMM-listed modules can be used in government-funded, open-access, and net-metering solar projects such as PM Surya Ghar and PM Kusum scheme and Solar Energy Corporation of India tenders. Only domestic produce are eligible for Production-Linked incentives.
“Suitable grandfathering provisions have been built in to protect projects already in the pipeline. The current order of MNRE, extends mandatory sourcing requirements from ALMM lists, already in place for modules and cells, one step further up the solar supply chain to include the ingots and wafers, which currently remains heavily import-dependent,” the MNRE said in a statement.
India has targetted adding 280 GW of solar capacity by 2030 and has installed about 132 GW as of November 2025. While it has in recent years ramped up domestic manufacturing of solar modules to about 91 GW as of June 2025, India is heavily dependent on China for sourcing the solar cells. As of September 2025, there were only six manufacturers with a combined capacity of 13 GW. The manufacturing capacity for ingots and wafers is even lower at 3 GW.
The Energy and Resources Institute (TERI), in a recent report, said that sans new wafer projects and large polysilicon manufacturing before 2028, India’s solar ambitions could be thwarted. India has also recently been slapped with a 126% duty on its solar exports to the United States – its largest export market – making it harder for its domestic manufacturers.
Union Minister for New and Renewable Energy Pralhad Joshi said on Wednesday  that this was a “decisive step” towards strengthening India’s solar manufacturing ecosystem. The introduction of ALMM List-III is expected to: drive investment into ingot and wafer manufacturing facilities in India; improve supply chain security and reduce vulnerability to import disruptions; ensure quality and traceability of solar components all the way from wafer to module; create skilled employment in upstream solar manufacturing, a press statement noted.
Published – March 18, 2026 08:05 pm IST
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Bailiwick Express News Jersey
BE in the know – the latest news for Jersey and Guernsey
Jersey Electricity has revealed that a project to install solar panels on fields in St Mary is still up in the air more than a year after the plans were “temporarily” withdrawn, amid questions from neighbouring residents over the project’s future.
The utility company announced in February 2025 that the planning bid for its Champs Verts scheme had been pulled in the wake of questions posed by the Cabinet Office, but said at the time that it intended to resubmit the application “in due course”.
JE has now stated that the project is still being considered as part of a “wider reassessment” of its Solar 5,000 programme to power 5,000 homes with locally-generated solar power by 2030.
“Residents now deserve to be told if Jersey Electricity intends to go ahead [with Champs Verts]
The decision to withdraw the application last year also came amid pushback from residents, including members of the Save This View campaign group.
In a recent statement, William Layzell, who leads the group, said: “It’s over a year since the planning application was withdrawn, partly, we believe, because of our campaign but also because of objections raised by the government’s Cabinet Office.”
Referencing a separate announcement by JE earlier this year about its decision to pull the plug on plans for a solar farm at Belle Fontaine, Mr Layzell added: “Residents now deserve to be told if Jersey Electricity intends to go ahead [with Champs Verts] or if this scheme, like the one in St Martin, is to be abandoned.
“No doubt these are questions which will be asked during the election campaign in May. Candidates and States Members will want to know how much JE has spent on these two schemes: one scrapped, the other unlikely to go ahead.”
Solar generation remains an important part of improving the resilience and diversity of Jersey’s electricity supply
In response, JE stated that the Champs Verts project “remains under review as part of a wider reassessment of the company’s Solar 5,000 programme”.
“Solar generation remains an important part of improving the resilience and diversity of Jersey’s electricity supply,” the statement continued.
“Local solar generation can help reduce daytime-peak demand, particularly during the summer months, while providing a stable long-term fixed-cost source of energy.”
The update comes not long after JE announced that it had agreed a partnership with the government that will see rooftop solar arrays installed across a range of public buildings.

editor@bailiwickexpress.com
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The Fleet solar project will be supported by a government-backed Contract for Difference (CfD) offtake agreement.
March 18, 2026
Asset manager Capital Dynamics has bought a planned 63MW solar PV project from German-owned renewables developer Baywa r.e.. 
The Fleet solar project, in north Hampshire, is due to begin construction in 2027, the firm said, and will be supported by a government-backed Contract for Difference (CfD) offtake agreement. It will likely begin commercial operations in 2028. 
“The UK remains one of our core markets for investment, underpinned by strong fundamentals. We continue to see sustained momentum for the wider energy transition at a time when more investment is needed to meet the UK’s dual energy security and climate goals,” said Barnet Coals, senior managing director at Capital Dynamics. 
This is the third UK solar project Capital Dynamics has bought from Baywa r.e.. In December, it announced the sale of two projects in Leicestershire and North Somerset with a combined capacity of just under 90MW. 
Related:Glasgow coffee roastery expands rooftop solar capacity to 422kW
“Fleet Solar Farm demonstrates the strength of our development capabilities and highlights the quality of the projects in our pipeline. We are delighted to have secured a CfD contract in AR7, which further enhances the project's long-term value,” said Sarah Drummond, director of commercial, risk and project delivery at Baywa r.e. UK & Ireland. 
The developer said that it will incorporate sheep grazing and wildflower meadows at the site near Fleet.
Baywa r.e. is currently developing a 140MW solar-plus-storage project in south Derbyshire which was greenlit by Energy Secretary Ed Miliband last June. The project is designated as a Nationally Significant Infrastructure Project (NSIP). 
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Will is a senior reporter who primarily covers the policy and geopolitics behind the energy transition, with a particular focus on manufacturing. 
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A joint venture between French oil giant TotalEnergies and Paris-headquartered renewables producer Eren Groupe, has submitted plans for one of Australia’s largest solar and battery energy storage projects for review under the local Australian environmental process.
The $2.8 billion Wak Wak project proposed by TE H2, proposed for a 3,400-hectare site near Humpty Doo, about 48 kilometres south of Darwin, is to include a 2.7 GW solar farm that would “allow for an optimized, year-round energy supply to the potential electricity off-takers.”
In its application documents, TE H2 said the concept design also includes 6 GWh of battery energy storage to “firm up the renewable energy supplied and to balance solar power generation with electricity consumption at downstream facilities, provide local network stability services, and serve as a backup to ensure a secure facility shutdown when needed.”
TE H2 said while “the project is currently at concept design stage,” the objective of the proposal is to generate and store renewable solar energy for both existing industry in the greater Darwin region, and potentially, for the generation of renewable green hydrogen.
“The ultimate end use of the solar energy is as a critical input to produce firm renewables energy supply to existing industrial end users on Middle Arm initially and to power green hydrogen production at the Middle Arm Precinct at a later stage,” TE H2 said.
Known as an application under the Environment Protection and Biodiversity Conservation (EPBC) Act, the federal government-administered EPBC review process aims to protect nationally threatened species and ecological communities. EPBC referral documents say renewable energy generated at the Wak Wak facility will be sent via a planned high-voltage overhead transmission line to Middle Arm where TE H2 has the Darwin H2 Hub in development, and potentially connect into the Darwin Katherine grid.
TE H2’s proposed Darwin H2 Hub is to include a 1 GW electrolyser capable of producing more than 80,000 tonnes of green hydrogen per annum for national and international markets.
Construction of the Wak Wak solar and battery facility is expected to commence in 2027, pending project approvals. It is likely the solar farm will be developed in stages with the first phase expected to be in the vicinity of up to 900 MW.
TE H2 said power for construction will include a combination of temporary solar and battery storage on site, likely supplemented by diesel generators during the establishment and early works phase.
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UNSW and ACAP win grant to build ties between emerging solar PV leaders in China and Australia  UNSW Sydney
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FLASH: Indonesian Triputra Group vi…  Mysteel
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China’s clean energy boom is saddled with a major challenge: what to do with all its old wind and solar equipment.
The country, which is the world leader in renewable energy capacity, has built solar and wind at a staggering pace. As of March 2025, China’s combined installed wind and solar capacity topped 1.48 billion kilowatts for the first time ever, surpassing thermal power.
But now the first wave of that buildout is aging out.
Wind turbines and solar panels are typically designed to last around 20 to 25 years. That means early projects are starting to be retired, and the volumes are huge. By 2050, decommissioned solar panels in China could total around 20 million tonnes. Retired wind turbine blades are expected to hit about 3 million tonnes by 2035.
That raises a big question: How do you recycle all of it?
State-owned China Energy Investment Corporation (CHN Energy), which says it has the world’s largest installed wind capacity, is trying to tackle what it calls the “last mile” of green energy – dealing with equipment at the end of its life.
Its total wind and solar capacity is close to 120 million kilowatts, or nearly 10% of China’s total.
After several years of development, CHN Energy launched a kiloton-scale solar module recycling demonstration line in October 2025. The facility was developed and built by its subsidiary, Longyuan Environmental Protection.
Longyuan Environmental Protection’s Zhangjiakou branch is expected to come online this year, with the capacity to process more than 10,000 tonnes of retired wind and solar equipment annually – that’s roughly the weight of 10,000 small cars.
Longyuan Environmental Protection has also established a recycling committee for retired wind and solar equipment within the China Association of Circular Economy. It has helped draft around 17 international, national, and industry standards tied to this growing sector.
The goal is to build a full life-cycle approach to clean energy – not just generating low-carbon electricity, but also making sure the equipment doesn’t become a long-term waste problem.
Hou Bo, deputy general manager of Longyuan Environmental Protection, said, “True green development lies in delivering green power while ultimately achieving a closed loop through comprehensive end-of-life solutions.”
China isn’t alone here. The global renewable buildout is accelerating, and every country faces the same issue as early projects age out.
Figuring out how to recycle solar panels and wind turbines at scale is critical for keeping clean energy truly clean.
It would be wise for countries and companies like CHN Energy to share best practices for recycling renewable waste.
Read more: China’s wind + solar revolution is shaking up the global energy game
If you’re looking to replace your old HVAC equipment, it’s always a good idea to get quotes from a few installers. To make sure you’re finding a trusted, reliable HVAC installer near you that offers competitive pricing on heat pumps, check out EnergySage. EnergySage is a free service that makes it easy for you to get a heat pump. They have pre-vetted heat pump installers competing for your business, ensuring you get high quality solutions. Plus, it’s free to use!
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EIB backs €260m Ireland solar portfolio  reNEWS.BIZ
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FLASH: Tongwei signs 1GW Module Coo…  Mysteel
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Plans to use small-scale solar panels at public housing sites have been unveiled by the Ministry of Home Affairs.
Alexa Lightbourne told the House of Assembly on Monday that the renewable housing initiative would look to expand renewable energy options to renters living in “apartment-style housing”.
Ms Lightbourne explained the project, run by the Department of Energy and the Bermuda Housing Corporation, would use panels designed to fit on a balcony or patio instead of on a roof, where they are typically placed.
She said that other “practical solutions” were being explored to reduce energy costs for renters in public housing developments.
Ms Lightbourne said a $200,000 grant would go towards a pilot renewable energy programme that would install balcony-mounted solar PV systems at selected housing developments.
She explained: “These systems are designed specifically for apartment-style buildings and can be installed without the need for rooftop infrastructure, making them particularly well-suited for public housing environments.
“The Bermuda Housing Corporation will play an essential role in the programme by co-ordinating resident engagement and facilitating the installation process, while the Department of Energy will maintain initiative oversight and provide technical co-ordination.”
Ms Lightbourne added: “This partnership represents an important part in expanding equitable access to renewable energy technology to those who can least afford it.
“By targeting these households who have historically had limited ability to participate in rooftop solar programmes, the initiative supports the Government’s broader goals of improving energy affordability, reducing electricity consumption and ensuring that the transition to cleaner energy benefits all Bermudians.”
The plans are expected to progress this year.
Ms Lightbourne’s comments came on the final day of the breakdown of the Bermuda Budget in the House.
The Ministry of Home Affairs was allocated $6.56 million — a 14 per cent boost when compared with its last budget.
The home affairs headquarters was estimated to receive $3.89 million, including $1.73 million for professional services and $1.72 million for salaries.
The Land Title and Registration Office would receive $1.87 million, while the Department of Energy was allocated $795,000.
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Solar Power World
By Billy Ludt | March 18, 2026
The Boulder Jewish Community Center has completed a rooftop solar installation at its LEED-certified campus in Boulder, Colorado, offsetting 80% of its electricity consumption.
A solar installation at the Boulder Jewish Community Center in Colorado. Credit: Namaste Solar
The 306-kWDC solar project, completed in late 2025, was developed in partnership with Namaste Solar, an employee-owned cooperative. The 614-panel system joins an existing 67-kW rooftop array.
This solar milestone was made possible by a collaborative funding effort. A $523,143 grant from Boulder’s Community Culture, Resilience and Safety Tax Program set the project in motion. Additional support came from Boulder County’s PACE program, Xcel Energy’s Solar Rewards, a loan from the Adamah Climate Action Fund and gifts from community donors. With this funding and anticipated federal IRA incentives, the project’s cost was largely covered, reducing financial barriers for the nonprofit Boulder JCC.
In addition to the environmental benefits, the solar investment is reduce approximately $1.8 million in total lifetime savings.
“Sustainability is woven into the fabric of the Boulder JCC,” said Executive Director Jonathan Lev. “This solar project allows us to lead by example, educating our community while ensuring that our operational savings go directly toward our mission-driven programming.”
Thirty-one Namaste Solar employees, from designers and engineers to project managers and installers, contributed to the project.
“We selected Namaste Solar because they’ve been doing this work for decades,” Lev said. “They started right here in Boulder, they are employee-owned and they have built a reputation rooted in high-quality work and conscientious business practices.”
A solar installation at the Boulder Jewish Community Center in Colorado. Credit: Namaste Solar
Boulder JCC’s main building is LEED certified, and the Milk and Honey Farm operates as a net-zero facility, with 100% of its energy needs met through on-site renewable generation.
“Our goal has always been to offset as much of our energy use as possible by fully utilizing our available roof space,” said Becca Gan Levy, farm and sustainability director. “Decarbonizing the grid is a critical priority, and this project achieves that while significantly lowering our operating expenses. Ultimately, these savings allow us to direct more resources into education, food access, and community-building, modeling what climate responsibility looks like in practice.”
In addition to installing the new system, the Boulder JCC has signed a five-year operations and maintenance agreement with Namaste Solar covering both the new array and its existing solar installation to ensure long-term performance and reliability.
“Working with an organization like the Boulder JCC is exactly why Namaste Solar exists,” said Alicia Creighton, co-owner and commercial project developer at Namaste Solar. “As a Certified B Corporation, supporting a mission-driven non-profit that prioritizes sustainability, aligns perfectly with our values.”
News item from Namaste Solar
Billy Ludt is managing editor of Solar Power World and currently covers topics on mounting, inverters, installation and operations.

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Cloudy skies this morning will become partly cloudy this afternoon. High 36F. Winds SSW at 5 to 10 mph..
Cloudy skies. Low 26F. Winds light and variable.
Updated: March 18, 2026 @ 5:00 am
Cloudy skies this morning will become partly cloudy this afternoon. High 36F. Winds SSW at 5 to 10 mph..
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Updated: March 18, 2026 @ 5:00 am
Connecting the Valley to Print and Digital
Toshiba: TLX9920, a photovoltaic-output photocoupler in a thin, long-creepage-distance SO6L package for SSR in automotive equipment.

Toshiba: TLX9920, a photovoltaic-output photocoupler in a thin, long-creepage-distance SO6L package for SSR in automotive equipment.
KAWASAKI, Japan–(BUSINESS WIRE)–Mar 17, 2026–
Toshiba Electronic Devices & Storage Corporation (“Toshiba”) has launched a photovoltaic-output photocoupler, “ TLX9920 ”, in a thin, long-creepage-distance SO6L package, for solid state relays (SSR) [1] in automotive equipment. Volume shipments start today.
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Gujarat led in both solar cell and module manufacturing
March 18, 2026
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India added nearly 119 GW of solar module and over 9 GW of solar cell capacity in 2025, according to Mercom India’s State of Solar PV Manufacturing in India 2026 report.
The manufacturing expansion was driven by demand from India’s large utility-scale solar project pipeline, residential rooftop targets, the PM Surya Ghar program, and the Approved List of Models and Manufacturers (ALMM) List-II domestic cell mandate.
As a result of these policy initiatives, the country’s cumulative module manufacturing capacity reached approximately 210 GW, while cumulative cell capacity stood at roughly 27 GW by December 2025. Of this, module capacity under ALMM List-I stood at 173.1 GW, while cell capacity under ALMM List-II was nearly 26.5 GW as of this report’s release. Currently, the ALMM-certified cell capacity accounts for only 15.3% of ALMM-certified module capacity.
Priya Sanjay, Managing Director at Mercom India, said the ALMM mandate was the primary driver of growth in the solar manufacturing segment. The pace is accelerated by the June deadline, when it becomes compulsory to use domestic modules with cells made in India for most projects, except behind-the-meter projects.
She added that the PM Surya Ghar program has increased demand, as the government has mandated domestic content requirements (DCR) for modules under the program. Additionally, several open access solar projects for commercial and industrial (C&I) customers are being operationalized, adding to the growth.
The top 10 manufacturers accounted for 44% of the cumulative module capacity and 99.5% of the cumulative cell production capacity, highlighting a high level of consolidation in the sector.
In terms of technology, monocrystalline cells accounted for more than 57% of production capacity, followed by TOPCon at over 39%. Polycrystalline cells accounted for a small share, approximately 3.5%.
“Domestic cell manufacturing capacity is expected to begin increasing on paper after March based on commissioning timelines, ahead of the ALMM domestic cell mandate taking effect in June. However, newly commissioned production lines typically take about eight months to stabilize and reach optimal yields. As a result, installed capacity may appear to rise after March, but the effective supply available to module manufacturers will increase more gradually, with meaningful availability likely emerging only toward the end of the year as new facilities complete their stabilization cycles,” said Raj Prabhu, CEO of Mercom Capital Group.
TOPCon dominated module manufacturing by the end of 2025, accounting for around 70% of the module production installed capacity, followed by monocrystalline modules at more than 25%. Polycrystalline and thin-film modules each accounted for roughly 2%.
Heterojunction Technology (HJT) module manufacturing capacity, accounting for approximately 1% of the total capacity added, was included for the first time.
“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,” added Prabhu.

Gujarat emerged as the leading module manufacturing hub as of December 2025, accounting for about 45% of module production capacity, followed by Rajasthan with 10% and Tamil Nadu with 7%.
In cell manufacturing as well, Gujarat led among states, accounting for 45% of the total production capacity. It was followed by Tamil Nadu and Karnataka at 16% and 13%, respectively.
Commenting on Gujarat leading the way in the solar manufacturing business, Sanjay said that the state is well-positioned geographically and has the basic infrastructure for solar manufacturing companies to establish their facilities.
“The state is close to Rajasthan and Maharashtra, major solar markets, contributing to Gujarat’s success. Also, in terms of exports and imports, it has ports, which give it the tailwind as compared to other states. The government is very keen on supporting existing industries and attracting new ones to the state. This has led to the growth of industry clusters in the state, which further contributes to the growth of the solar manufacturing business,” Sanjay noted.

Despite strong domestic capacity additions, India imported around 99 GW of solar modules and cells in 2025, with cells accounting for 75% of the imports.
Domestic manufacturers exported roughly 5 GW of modules and 192 MW of cells. The U.S. emerged as the largest market for modules, with 96.8% of total exports going to the country, while 57% of cell exports went to the UAE.
Mercom’s Mercom India’s State of Solar PV Manufacturing in India 2026 is 131 pages long and covers all facets of India’s solar PV manufacturing market, including an overview of demand and supply, top manufacturers, market outlook and projections, manufacturing trends, and other details.
For the complete report, visit: https://www.mercomindia.com/product/state-solar-manufacturing-india-2026
Rakesh Ranjan
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© 2026 by Mercom Capital Group, LLC. All Rights Reserved.

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As part of its ongoing Spring Power Station Sale, you can pick up the Anker SOLIX F3800 Portable Power Station with a FREE Outdoor Kit ($189 value) down at $1,804.05 shipped, after using our exclusive savings code 9TO5DEALS5 at checkout, beating out its parallel Amazon pricing by $96. Don’t be fooled by the $3,999 MSRP that it’s listed with, as you can much more often find it starting down between $2,399 and $2,599 since mid-December. Discounts over the last few months have mostly been keeping pricing around $2,000, though we have seen some occasional drops to $1,899 and some flash sale cuts to the $1,799 low. The exclusive deal that only our readers can get here provides you with $795 off the going rate ($2,195 off the MSRP) landing it just $5 shy of the all-time lowest price we have tracked. Head below to learn more, as well as browse the lineup of deals for it and its upgraded F3800 Plus variant.
Features scalable 3,072Wh LiFePO4 capacity up to 24kWh maximum, 11 output ports (including TT-30R RV port), 3,600 to 7,200W maximum output power, and more.
Now, I’m sure you’re wondering what the differences are between Anker’s standard SOLIX F3800 and newer SOLIX F3800 Plus power stations and whether the latter is worth the extra cost, and to that I say it all depends on what kind of port configuration and/or maximum solar input you want for your needs. Both models cover RV and EV support, though the standard F3800 brings along a NEMA 14-50 240V port for RV needs, while the F3800 Plus trades that in for a 120V TT-30R, as well as offering a greater 3,200W max solar panel input over the standard’s 2,400W input maximum. The F3800 Plus also sports a specialized home power panel port that allows for charging from a gas generator, as well as a home panel, making it more efficient as a home backup solution.
After that, both power stations offer much of the same features/performance, starting from their 3,840Wh LiFePO4 battery capacity that you can invest in to expand up to a 26.9kWh maximum. There are 15+ total output ports (including those varying configurations), from which these stations provide devices/appliances/more with up to 6,000W of power on the regular, with the potential to surge up as high as 9,000W. Aside from the solar/gas generator/home panel charging mentions above, they both also offer typical AC outlet recharging and charging via a car auxiliary port.
***Note: keep in mind that we have not factored the bonus 5% savings into the prices listed below, so make sure to use our exclusive code 9TO5DEALS5 at checkout for the very best rates during this event.
You can check out the full lineup of deals in our original coverage of Anker’s SOLIX Spring Sale here, which is now seeing increased discounts up to 67% off, along with five different FREE gifts/bundles, and our exclusive savings on any purchases over $1,000.
FTC: We use income earning auto affiliate links. More.
Features scalable 3,072Wh LiFePO4 capacity up to 24kWh maximum, 11 output ports (including TT-30R RV port), 3,600 to 7,200W maximum output power, and more.
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Partly cloudy. High 71F. Winds SW at 10 to 20 mph..
Mainly clear. Low 52F. Winds SSW at 5 to 10 mph.
Updated: March 18, 2026 @ 4:21 am
Toshiba: TLX9920, a photovoltaic-output photocoupler in a thin, long-creepage-distance SO6L package for SSR in automotive equipment.

Toshiba: TLX9920, a photovoltaic-output photocoupler in a thin, long-creepage-distance SO6L package for SSR in automotive equipment.
KAWASAKI, Japan–(BUSINESS WIRE)–Mar 17, 2026–
Toshiba Electronic Devices & Storage Corporation (“Toshiba”) has launched a photovoltaic-output photocoupler, “ TLX9920 ”, in a thin, long-creepage-distance SO6L package, for solid state relays (SSR) [1] in automotive equipment. Volume shipments start today.
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© 2025 THE COOL DOWN COMPANY. All Rights Reserved. Do not sell or share my personal information. Reach us at hello@thecooldown.com.
“Client response to the … initiative has been very positive.”
Photo Credit: LinkedIn
Mayo is about to add some honey — and it has nothing to do with sandwiches. 
Energy developer Astatine is bringing 300,000 native honeybees to its solar farm in Mayo County, Ireland, according to Mayo Live. 
The solar farm has 32,000 panels that supply energy to the Ballina Beverage Company. It’s part of the drink-maker’s efforts to clean up operations, and the arrays are delivering results. More than 8,800 tons of harmful air pollution are prevented each year, while enough electricity to power 1,150 homes annually is estimated to be saved, according to Ballina. 
Solar energy is one of the cheapest and fastest power sources to develop to meet increasing grid strain and surging electricity prices. Homegrown power via rooftop panels can provide great value for ratepayers. And EnergySage can help anyone who is ready to explore their options by providing curated and competitive installation estimates. 
Want to go solar but not sure who to trust? EnergySage has your back with free and transparent quotes from fully vetted providers in your area.
To get started, just answer a few questions about your home — no phone number required. Within a day or two, EnergySage will email you the best options for your needs, and their expert advisers can help you compare quotes and pick a winner.
The addition of bees on large solar farms is intended to boost biodiversity as well. They will be placed on the sites during the summer with regular inspections by pollinator experts. 
“Solar farms already reduce carbon emissions, but they can also be biodiversity hubs,” Astatine CEO Tom Marren told ML. “By introducing beehives, we are strengthening local ecosystems, supporting farmers, wildlife, and the wider community. This initiative shows how renewable energy can work hand-in-hand with nature.”
Other solar developers are incorporating farming within array boundaries as part of agrivoltaic systems. Often, the panels benefit crops or animals by offering shade. The practice also makes vital land available for farming and can even aid panel function. Inside Climate News reported that plants cool panels through evaporation. 
When hives are present, panels provide cover for bees — insects that will, in turn, pollinate nearby crops. About 35% of the planet’s food supply relies on bees and other pollen-carrying critters, according to the United States Department of Agriculture. 
FROM OUR PARTNER
Want to go solar but not sure who to trust? EnergySage has your back with free and transparent quotes from fully vetted providers that can help you save as much as $10k on installation.
To get started, just answer a few questions about your home — no phone number required. Within a day or two, EnergySage will email you the best local options for your needs, and their expert advisers can help you compare quotes and pick a winner.
In Mayo, Astatine is also planting wildflowers and building contraptions to help support bug health. That’s in addition to a sweet byproduct: honey. 
“Client response to the beehive initiative has been very positive. We plan to roll out hives at all our project sites nationwide and continue exploring other ways to enhance biodiversity across Ireland and beyond,” Marren told ML. 
Which of these savings plans for rooftop solar panels would be most appealing for you?
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Click your choice to see results and earn rewards to spend on home upgrades.

For homeowners, EnergySage’s expertise can help customers save up to $10,000 on upfront costs. Its handy mapping tool compares prices and available incentives by state, so you know you are getting the best deal. Adding a battery backup solidifies another layer of protection, especially against blackouts. What’s more, the stored energy can also be used when grid electricity is most expensive, limiting your exposure to increasing rates. 
EnergySage’s experts can help you find the right pack for your home that fits your budget with more installation cost comparisons. 
💡Go deep on the latest news and trends shaping the residential solar landscape
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By Meg Flippin, Benzinga
DETROIT, MICHIGAN – March 16, 2026 (NEWMEDIAWIRE) – The marine solar panel market is projected to reach $5 billion by 2035, growing at a CAGR of 13.1% over 2025-2035, and Ascent Solar Technologies Inc. (NASDAQ: ASTI) could be one to watch. As the developer of featherweight, flexible and durable CIGS thin-film photovoltaic (PV), not only are its marine-ready solar panels durable and saltwater-resistant, the company reports they are also cost-effective. Ascent counts several big names, from NASA’s Marshall Space Flight Center to the Georgia Institute of Technology, as partners and is increasingly expanding into marine applications.
Powering Water Vessels With An Edge 
Ascent Solar’s CIGS solar cells are finding interest in the marine industry because they are thin-film PV cells that weigh very little and are flexible. Since they perform well in low light, they are becoming an increasingly popular choice for space exploration, drones and surface and underwater vehicles (both military and commercial). What Ascent Solar says gives it an edge over competitors is its ability to deliver solar arrays in six to eight weeks, much faster than rivals that Ascent says have lead times of nine to 12 months. The company is betting that its manufacturing prowess will be a big advantage for OEM boatbuilders and integrators needing responsive supply chains.
It doesn’t hurt that Ascent Solar already has a history in the marine market. The company has delivered modules for testing in saltwater and for underwater monitoring applications, demonstrating the potential of remote systems under extreme conditions. This is critical for ocean monitoring, offshore platforms and long-range vessels. Their performance in low light and extreme temperatures also fits unpredictable marine environments. The company also believes its patented Monolithic Integration (MI) technology gives it an edge. This tech allows panels to continue generating power even if they are partially damaged or punctured. This is critical for solar-powered boats in the deep ocean; if a traditional solar panel is damaged by a wave or heavy winds, all of its cells typically fail.
Mooring The Customers 
With its expertise, it is no surprise that Ascent Solar is becoming more active in the maritime market. An ocean monitoring company is currently testing the functionality and durability of Ascent’s PVs in aquatic terrestrial applications to enable persistent equipment operation. Meanwhile, Georgia Tech is integrating solar arrays directly into the wings of unmanned aerial vehicles (UAVs) designed for ocean monitoring. These solar-powered seaplanes are being developed for persistent, long-range maritime surveillance. Ascent Solar sees its panels as a solution for persistent ocean buoys, sensors, autonomous underwater vehicle (AUV) surface charging and electric boat hulls. Beyond traditional surface PVs, the company’s tech has drawn interest from developers of autonomous vehicles, a niche but rapidly expanding area within the broader marine solar market, reports the company.
By combining rapid manufacturing with extreme durability, Ascent Solar is positioning itself to be at the helm of the next generation of green ships and applications. To learn more about Ascent, click here. 
Featured image from Shutterstock.
This content was originally published on Benzinga. Read further disclosures here.
This post contains sponsored content. This content is for informational purposes only and is not intended to be investing advice. 
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RenewSys India Inaugurates 3 GW Solar Module Manufacturing Facility in Maharashtra  SolarQuarter
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10 GW Agrivoltaic Capacity Proposed in PM-KUSUM 2.0 
India plans to introduce a dedicated 10 GW component under the upcoming Pradhan Mantri Kisan Urja Suraksha evam Utthan Mahabhiyan (PM-KUSUM) scheme 2.0 to promote the co-location of solar panels with crops. It aims to create a new model for decentralized renewable energy generation in India, announced the Ministry of New and Renewable Energy (MNRE). It will enable farmers to generate electricity while continuing agricultural production on the same land. The Union Minister of New and Renewable Energy (MNRE) Pralhad Joshi said the country’s agrivoltaic potential is estimated at 3,000 GW to nearly 14,000 GW, which can significantly enhance farmers’ earnings. The move is part of efforts to expand decentralized renewable energy in rural areas and support India’s target of 500 GW of non-fossil fuel capacity by 2030.  
India introduced the PM-KUSUM scheme in 2019 to encourage the use of solar PV technology in agricultural activities. Divided into 3 components (including 10 GW decentralized ground-mounted or stilt-mounted grid-connected solar or other renewable energy capacity), it targets 34.8 GW of solar PV capacity by March 31, 2026, as per the scheme’s latest revision. 
ReNew Raises $95 Million with Stake Sale 
ReNew Energy Global Plc has raised $95 million in equity investment, led by LeapFrog Investments, which has directly committed $50 million. The remaining investment comes from the Emerging Market Climate Action Fund (EMCAF) and Carlyle AlpInvest. After the closing of the investment, the consortium will acquire approximately 11.3% stake in ReNew Green Energy Solutions Private Limited, the commercial and industrial (C&I) platform of ReNew Energy. The subsidiary’s current committed capacity across multiple states stands at 2.5 GW, of which 2 GW is already online. Within this portfolio, it has 1.3 GW with long-term agreements with global technology giants, including Meta, Amazon, and Google. “This partnership helps us scale solutions that reduce emissions, strengthen energy security, and support India’s industrial growth in a way that is both sustainable and inclusive,” said ReNew Chairman & CEO Sumant Sinha. On a gross basis, ReNew Energy had a clean energy portfolio of around 19.2 GW, including 1.5 GW of battery energy storage systems (BESS) as of February 12, 2026 (see ReNew Energy Improves Q3 FY26 Revenue; Narrows Net Loss).  
Sunsure Energy Raises ₹606 Crore for Solar Expansion 
Indian independent power producer (IPP) Sunsure Energy has secured ₹606.22 crore in debt financing from Aseem Infrastructure Finance and RBL Bank. Of the total funding, INR 461.76 crore from Aseem Infrastructure will be used to develop solar projects in Maharashtra and Uttar Pradesh. The remaining INR 144.46 crore in refinancing from RBL Bank will support Sunsure’s solar project in Augasi in Uttar Pradesh. Altogether, the financing will support more than 242 GW of solar capacity, catering to C&I consumers under long-term power purchase agreements (PPAs). Upon completion, these will generate approximately 300 million units annually, stated company management. 
NISE Pilots Solar Boat for Fishing 
The National Institute of Solar Energy (NISE) is conducting a study on the feasibility of using solar power in boats, including those used for fishing. The institute has partnered with the Centre for Sustainable Energy and Environment (CSEE) to implement a pilot project and conduct trial runs, informed Union Minister of State for MNRE, Shripad Yesso Naik. As part of the initiative, a pilot solar boat for fishermen has been developed. Key components such as PV modules, batteries, charge controllers, and motors have been procured and tested at NISE, while the fiber boat was fabricated at Uppada Harbour. System integration, field trials, and performance validation are currently underway. 
Tata Power, Tata Capital Unveil Pay-as-you-Save Solar Plan 
Tata Power Renewable Energy Limited (TPREL) has partnered with Tata Capital to launch the SunSmart Flexi EMI scheme aimed at C&I customers adopting solar energy solutions. The financing model follows a ‘pay-as-you-save’ approach. Under this, businesses will be able to install rooftop solar systems with flexible EMI repayments or lease rentals that align with the savings generated from solar power. TPREL says this scheme will lower the upfront investment barrier and help enterprises transition to clean energy while managing cash flows more effectively. The companies said the scheme is designed to support wider solar adoption among industries across automobile, textile, IT, steel, HVAC, cold storage, FMCG, and quick commerce, among others. 
800 MW Solar PV Module Factory in Haryana 
Solar and e-mobility solutions provider Eastman Auto & Power Limited recently commissioned an 800 MW solar PV module manufacturing facility in Sonipat, Haryana. The factory produces solar modules that comply with the government’s domestic content requirement (DCR) norms and MNRE standards. With this fab online, Eastman says its portfolio comprises solar modules, grid-tie, off-grid, and hybrid inverters and advanced energy storage batteries. Eastman Managing Director Shekhar Singal said, “Our focus is on building a strong domestic solar manufacturing ecosystem under the Make in India vision while driving adoption of integrated ‘Solar with Storage’ solutions that deliver reliability and energy independence.” 
Waaree Energies Disputes Arbitration Claim by Enel 
Enel Green Power Development has filed a request for arbitration against Waaree Energies Limited (WEL) regarding the sale of Enel Green Power India Private Limited (EGP India). Enel filed the arbitration request with the International Court of Arbitration of the International Chamber of Commerce (ICC). Enel alleges WEL breached the sale and purchase agreement signed on January 10, 2025, and is seeking claims for damages and loss of profits. WEL says it disputes the allegations and intends to contest the claims. In January 2025, WEL acquired EGP India for INR 7.92 billion under a share purchase agreement (see Italy’s Enel Green Power Sells India RE Portfolio To Waaree Energies). 
TaiyangNews 2024

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Recent studies forecast Australia is on the precipice of a rooftop solar and household battery boom, predicting record breaking installation numbers driven by falling battery and solar module prices, government rebates and cost-of-living pressures.
Image: pv magazine Australia
From pv magazine Australia
Recent studies forecast Australia is on the precipice of a rooftop solar and household battery boom, predicting record-breaking installation numbers driven by falling battery and solar module prices, government rebates and cost-of-living pressures.
New research by Sydney-based clean energy installer Green.com.au has predicted a 95% jump in demand for solar installations by New South Wales (NSW) households, on the back of the energy regulator’s announcement that energy prices will increase 9.7% from 1 July 2025.
Describing it as a surge well above the national average, in line with NSW mortgage costs that are 31% above the national average, the analysis found NSW residents could install up to 188,814 solar systems in the 2025/26 financial year, nearly double the 97,077 systems installed in 2024.
Green Founder Dave Green said solar has moved from a nice-to-have to a financial necessity.
“Over the next year, we’re forecasting nearly 190,000 new installations across NSW: double last year’s numbers,” Green said.
“When you combine a near 10% energy price rise with the state’s average new mortgage being 31% higher than the national average, it’s no surprise.”
The study’s findings show homeowners thinking about installing solar rose from 21.5% to 42% chasing a potential $110 million (USD 71.5 million) in savings annually across the state.
The Climate Council has also forecast a boom in residential battery sales in line with state and government battery rebates and a drop in battery prices, finding one in two Australians want a household battery with rooftop solar.
Climate Councillor and energy expert Greg Bourne said Australia already generates an excess of clean, reliable, renewable energy from Australia’s abundant sun and wind.
“So, rather than simply letting it go to waste and missing out on the savings, batteries will help soak it all up and put it to good use during periods of high demand,” Bourne said. “As our transport fleet progressively electrifies, those batteries can also help our grid and provide extra resilience to the system overall.”

In South Australia, more than 7% of the state’s households utilize battery storage, while in the Northern Territory (NT), 15.9% of homes with solar also have a battery. Western Australia (WA) ranks first in the country for the number of big batteries in service or being commissioned, and Victoria for its rollout of 140 community batteries,
Climate Council Fellow and energy expert Andrew Stock said while the states are making headway in household, community, and grid-scale battery storage, more must be done, and faster, to ensure consumers reap the benefits.
“Installing more batteries means more gigawatts of renewable energy we can store. The return on investment for communities: lower bills, less climate pollution from polluting coal and gas, and a more resilient grid,” Stock said.
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Increased solar deployment and stricter enforcement of renewable purchase obligations across states and industries can help Indian manufacturers get over a volatile period and position themselves to compete better in a global market, according to Bengaluru-based think tank Climate Risk Horizons.
Climate Risk Horizons
The decline in India’s solar module exports to the US, due to tariff measures introduced by the Donald Trump administration, presents an opportunity to boost India’s energy security by accelerating domestic solar power deployment, suggests a new analysis by Bengaluru-based think tank Climate Risk Horizons.
The report says increased solar deployment and stricter enforcement of renewable purchase obligations across states and industries can help Indian manufacturers get over a volatile period and position themselves to compete better in a global market.
Solar module production in India has grown strongly, making the nation a net exporter, with the US as the major buyer. From FY 2022 to FY 2024, India’s PV module exports to the US rose nearly tenfold.
However, the trade tariffs imposed by the Trump administration in 2025 have since reduced India’s solar exports drastically. From August to September 2025, India’s solar module exports dropped from about $134 million to roughly $80 million, after a blanket 50% tariff was imposed on all export goods. Module costs in the US increased 31%, squeezing profit margins that typically range between 40–60% in developed markets.
Since the beginning of February 2026, the tariff rates have changed every few days. As of early March, Indian-made solar modules incur a 126% tariff in the US.
In a time of volatile geopolitics and policy by tweet, this tariff war reflects the risk of over reliance on, and concentration of, export markets. To strengthen the export resilience of its solar sector, India must look for new export markets in other developed countries, such as the EU, which primarily imports solar modules from China. While ramping up exports to the EU could take time, the report suggests that India must quickly leverage favourable factors like reduced GST rates on solar, latent industrial demand for renewable electricity and the need to cut energy imports to scale up domestic solar manufacturing.
“Enforcing the Renewable Purchase Obligation (RPOs) for India’s heavy industry is a tool that has been neglected too long. Heavy industries are required to source about 30% of their electricity consumption from renewable sources but almost none of them meet this target,” Vishnu Teja, author of the report. “If India’s top companies across cement, aluminium, steel, and fertiliser industries were to meet their RPOs, that alone would translate to about 19 billion units (BU) of annual renewable electricity demand. We estimate that 10 GW of solar PV would be needed to meet the 30% RPO and 50 GW to ensure that all electricity used by these companies comes from RE. This would boost demand for domestically-produced panels and lower industrial energy costs at the same time.”
GST 2.0, introduced in September 2025, reduced the GST for solar panels from 12% to 5%, with the government estimating a capital cost reduction of INR 20–25 lakh per MW, acting as an incentive for solar developers.
While India’s module manufacturing capacity can meet current domestic demand, the combined manufacturing capacity of components such as wafers, ingots, and polysilicon does not exceed 3 GW. India relies on China’s export—which controls more than 90% of the market in each of these verticals—for the same. An increase in demand for domestic renewable electricity can push the Indian manufacturers towards vertical integration.
“Recent volatility in the energy markets, whether reflected in tariffs on India’s solar exports or restrictions on oil imports, reinforce the need for greater energy security,” said Ashish Fernandes, Director of Climate Risk Horizons. “The good news is that solar is cheap and getting cheaper. Increasing domestic RE deployment will reduce India’s dependency on imported coal and, eventually, oil and gas as well. In 2024, India imported 30% of its annual coal for electricity at a cost of USD 21 Billion. By strengthening domestic RE capacity, India can not only secure greater energy independence but also conserve foreign exchange.”
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“[They] accumulate and interfere with the function of cells responsible for processing dead cells in multiple organs.”
Photo Credit: iStock
Two decades after a marine biologist coined the term “microplastics,” researchers are still uncovering how this form of pollution affects human health.
A new study, published in the journal Immunity, identified one way in which polystyrene microplastics appear to disrupt a key immune function. 
Microplastics, defined as plastic particulate matter smaller than 5 millimeters, evaded notice until 2004.
Since that time, researchers have been working to learn how they impact the environment, wildlife, and human health.
According to Wired, the study was authored by an international team of researchers affiliated with Memorial Sloan-Kettering Cancer Center, a prominent and top-rated oncology facility.
In the course of the study, the authors focused on immune cells called phagocytes, white blood cells that perform an important function: consuming and clearing dead cells, foreign matter, and other pathogens from the body.
When efferocytosis — the process by which phagocytes routinely clear away unwanted cellular material — is disrupted, humans are more vulnerable to diseases, inflammation, and autoimmune conditions.
The authors observed that lab mice exposed to polystyrene microplastics had “significantly impaired” immune function. Co-author Justin Perry told Wired that the findings could explain a global dip in male fertility.
“We found that microplastics accumulate and interfere with the function of cells responsible for processing dead cells in multiple organs: lung, liver, and testis. This may be contributing to the worldwide increase in male infertility,” Perry said.
Twenty years might sound like a significant interval for researchers, but when it comes to microplastics, studies like this show just how much we don’t know about them.
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One thing that’s well established is how pervasive microplastics have become in the environment and in the bodies of animals and people. 
Microplastics have consistently turned up in Earth’s most remote corners, even in places humans can’t reach. Plastic can take centuries to break down, shedding microplastics over time.
Study after study has shown that microplastics pose risks to the environment, wildlife, and people; they’ve been linked to a wide array of negative human health impacts, including heart attacks and some cancers.
One of the most insidious dangers of microplastics is their small size, given their massive impact on the environment and life on Earth, as Perry acknowledged.
“I was skeptical at first that microplastics would have any meaningful effect on phagocytosis. Now it is clear that I was wrong,” he admitted.
World leaders have for years sought to pass a global plastics treaty to rein in the production of new plastic, but talks have repeatedly stalled.
In the meantime, simply using less plastic and replacing your most-used items with non-plastic alternatives significantly reduces direct exposure.
Get TCD’s free newsletters for easy tips to save more, waste less, and make smarter choices — and earn up to $5,000 toward clean upgrades in TCD’s exclusive Rewards Club.
© 2025 THE COOL DOWN COMPANY. All Rights Reserved. Do not sell or share my personal information. Reach us at hello@thecooldown.com.

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China Energy Leads Circular Economy Push For Recycling Retired Solar And Wind Infrastructure  SolarQuarter
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Ireland based Power Capital Renewable Energy Ltd has signed financing for Project Dolmen Solar PV in Ireland. The project includes four solar photovoltaic plants with a combined capacity of 395 MW. Total project cost is estimated at €250 million, with €100 million from European Investment Bank (EIB). The financing was signed on 12 March 2026 following approval in February 2026. The projects will operate under RESS-3 and RESS-4 contracts for difference schemes. Electricity generated will support Ireland’s renewable capacity and reduce reliance on fossil fuels. EIB will provide senior debt and structuring support under its renewable energy financing framework.

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US tariffs slash India’s solar exports by 35%: Report  Down To Earth
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Cumulative solar module manufacturing capacity reached around 210 GW as of Dec. 31, 2025, while cell manufacturing capacity totaled about 27 GW, according to Mercom’s new report.
Emmvee solar cell facility
Emmvee
India added 119 GW of solar module manufacturing capacity and more than 9 GW of cell capacity in calendar year 2025, according to a new report by Mercom India’s newly released report, State of Solar PV Manufacturing in India 2026.
The report attributes the capacity additions to demand from India’s large utility-scale solar project pipeline, residential rooftop targets under the PM Surya Ghar program, and the Approved List of Models and Manufacturers (ALMM) List II domestic cell mandate.
Cumulative module manufacturing capacity reached around 210 GW as of December 2025, while cell manufacturing capacity totaled about 27 GW. Of this, module capacity under ALMM List I stood at 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 at 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,” added Prabhu.
A total of 99 GW of solar modules and cells were imported in 2025. Modules accounted for 25% of imports, while cells constituted 75%.
Domestic manufacturers exported around 5 GW of solar modules in 2025, with the United States accounting for 96.8% of shipments. Cell exports totalled 192 MW, with the United Arab Emirates as the leading destination, accounting for 57% of exports.

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Toshiba Electronic Devices and Storage Corporation has released a new photovoltaic-output photocoupler designed for use in solid state relays (SSR) within automotive equipment. Volume shipments of the TLX9920 have begun.
The component is housed in a thin SO6L package with a long creepage distance, targeting applications where high isolation voltage and compact form factor are required.
The release comes as the automotive industry moves increasingly toward solid state relays in place of traditional mechanical relays. SSRs have no physical contacts, which eliminates contact wear and reduces the need for regular maintenance – a characteristic that supports the growing demand for longer-life relay units in vehicles.
As automotive electrical systems become more complex, particularly with the rise of battery management systems, onboard chargers and inverters, the shift toward SSR is expected to continue.
The TLX9920 is designed to function as a gate driver for high-voltage power MOSFETs used in SSR applications. When combined with a high-voltage power MOSFET, it can achieve high-voltage, high-current switching that photorelay components alone cannot deliver.
The device is housed in an SO6L package measuring 3.84 x 10.0 x 2.1 mm, with a creepage distance of more than 8 mm. This enables a high isolation voltage rating of 5,000 Vrms.
Toshiba noted that the IEC 60664-12 international standard requires a creepage distance of 5.6 mm or more for applications in environments with pollution degree 2 and an operating voltage of 400V or above. The TLX9920 exceeds this requirement.
The component is qualified to AEC-Q101, the reliability standard for automotive electronic components.
The TLX9920 operates across a temperature range of -40 to 125 degrees Celsius. It delivers an open voltage of 13.5V minimum and a short-circuit current of 8 microamps minimum at an input forward current of 10 mA.
Turn-on time is rated at 0.6 ms typical with a 1.0 ms maximum, while turn-off time sits at 0.1 ms typical with a 1.0 ms maximum. The trigger LED current is rated at a maximum of 3 mA.
While the primary target is automotive equipment, including battery management systems, onboard chargers and inverters, Toshiba also positioned the TLX9920 for use in energy storage systems and industrial power equipment.
The company described the component as suitable for high-voltage systems and harsh environmental conditions across a range of switching applications.
Toshiba Electronic Devices and Storage Corporation develops semiconductor and storage products including discrete semiconductors, system LSIs and HDD products. The company employs approximately 17,000 people worldwide.
Last Updated on March 18, 2026 by Nick Ross
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by Gourav Singh | March 18, 2026 4:56 pm
Synopsis: Solar stocks rallied after India announced a June 2028 mandate for domestically produced ingots and wafers, with key players gaining 6.5–10.3%, reflecting optimism for local manufacturing growth.
The article outlines India’s upcoming June 2028 mandate requiring solar projects to use domestically produced ingots and wafers, highlighting its impact on reducing imports, boosting local manufacturing, attracting corporate investments, and supporting the country’s renewable energy target of 500 GW by 2030.
India plans to implement a new rule from June 2028 requiring all solar power projects to use domestically produced key components, including ingots and wafers. Currently, the country relies heavily on imports, primarily from China, for these essential solar panel materials.
This policy is designed to reduce dependence on foreign suppliers and foster the development of a fully integrated domestic solar manufacturing ecosystem. By promoting local production, India aims to strengthen its renewable energy sector while creating new industrial and employment opportunities.
For companies, the rule signals a significant push to invest in India-based solar manufacturing. Firms like Waaree and others are already planning large-scale investments, supporting India’s goal of achieving 500 GW of clean energy capacity by 2030 and boosting energy self-reliance. Here are the stocks that came into focus as the new rule came out
Incorporated in December 1990, Waaree Energies Limited is an Indian manufacturer of solar PV modules with an aggregate installed capacity of 12 GW. WEL has five solar module manufacturing facilities in India, with an international presence. Beyond manufacturing, Waaree Renewables Technologies Ltd offers turnkey EPC services, rooftop systems, and services related to green hydrogen.
With a market capitalization of Rs 91,464 crore, the share of this company is up by 10.25  percent, closing at Rs 3,177.40 per share. As of Q3 FY26, the company operates with a module production capacity of 23 GW and a cell manufacturing capacity of 5.4 GW, reflecting its strong scale in solar production.
Incorporated in 2015, Insolation Energy Ltd is engaged in the business of manufacturing solar panels and modules of high efficiency of various sizes. The company’s 200 MW SPV Module manufacturing unit is located in Jaipur, spread over more than 60,000 sq. ft. ft area with the latest machinery.
With a market capitalization of Rs 2,214 crore, the share of this company is up by 7.89  percent, closing at Rs 100.50 per share. As of Q3 FY26, the company has a solar module production capacity of 5.5 GW, with no existing solar cell capacity. It plans to expand by 1.5 GW for modules and 4.5 GW for cells, targeting Q3 FY27 for completion, supporting revenue growth and backward integration.
Borosil Renewables is engaged in manufacturing extra clear patterned glass and Low Iron Solar Glass for application in Photovoltaic panels, Flat plate collectors, and Greenhouses. Operates a state-of-the-art facility in Gujarat with a total capacity of 1,350 tons per day (TPD), with plans to further increase capacity.
With a market capitalization of Rs 6,145 crore, the share of this company is up by 6.55  percent, closing at Rs 438.40 per share. As of Q3 FY26, the company operates with a production capacity of 1,000 TPD (Tons Per Day), equivalent to approximately 6.5 GW of energy, highlighting its strong operational scale.
Disclaimer: The views and investment tips expressed by investment experts/broking houses/rating agencies on tradebrains.in are their own, and not that of the website or its management. Investing in equities poses a risk of financial losses. Investors must therefore exercise due caution while investing or trading in stocks. Trade Brains Technologies Private Limited or the author are not liable for any losses caused as a result of the decision based on this article. Please consult your investment advisor before investing.

Gourav is a financial analyst at Trade Brains with over two years of active stock market trading experience. He holds the NISM Series VIII certification, reflecting strong expertise in equity markets, financial analysis, and investment research.
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ITI Clarifies Solar PV Manufacturing Tender Status Following BSE Query  scanx.trade
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India extends domestic sourcing mandate to solar wafers, ingots for RE projects. How this aims at curbing Chinese imports  The Indian Express
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SRP building new solar power farm  FOX 10 Phoenix
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