According to Hydro’s official website on March 12, after Qatalum’s natural gas supplier confirmed that it would maintain a lower supply level, Qatalum decided to stop further production cuts and shutdowns and maintain an operating rate of 60. These production cuts were carried out safely and in a controlled manner, and with the operating rate maintained at 60, this improved the conditions for a future restart. It is not yet known when the restart will begin.

Recently, CIMC Enric and PT SAMATOR Group , Indonesia’s largest industrial gas and energy services provider, officially signed a strategic cooperation framework agreement in Jakarta. Leveraging their respective strengths, the two parties reached a long-term partnership to jointly promote the optimization of the energy structure in Indonesia and Southeast Asia, as well as green and sustainable development. PT SAMATOR Group is a leading industrial gas enterprise in Indonesia, with business spanning multiple sectors including healthcare, oil and gas, and metallurgy, and with a well-established local market network and operating resources. According to the agreement, the two parties will focus on in-depth cooperation in five major areas: the entire industry chain of industrial gases, natural gas storage and transportation equipment, EPC for energy projects, digital after-sales services, and new business development. CIMC Enric will leverage its strengths in the design, manufacturing, and system integration of energy equipment, together with the other party’s local resources, to jointly advance the implementation of clean energy projects such as industrial gases, hydrogen storage and transportation, and new energy, thereby supporting Indonesia’s energy transition and industrial upgrading. Ju Xiaofeng, Vice President of CIMC Enric, and Rachmat Harsono, Chief Executive Officer of PT SAMATOR Group, signed the agreement on behalf of their respective parties. Ju Xiaofeng said that this cooperation was the result of resource synergy and demonstrated the company’s determination to deepen its presence in the Indonesian market; Rachmat Harsono said that the cooperation would help further strengthen the Group’s local business and expand the space for both parties in markets outside China.

On March 5, the People’s Government of the Inner Mongolia Autonomous Region officially issued the “Outline of the 15th Five-Year Plan for National Economic and Social Development of the Inner Mongolia Autonomous Region,” clearly listing hydrogen energy storage, rare earth new materials, and green hydrogen-ammonia-methanol as strategic priorities, accelerating the development of the entire industry chain for green hydrogen, and building a nationally important high ground for the energy storage industry, thereby charting a clear path for energy transition and industrial upgrading. I. Hydrogen Energy Storage: Building the Entire Industry Chain and Sprinting Toward an Energy Storage Scale of 60 million kW The Outline proposed to expand and strengthen the hydrogen energy storage industry , with the core goals and measures as follows: Full-chain deployment of green hydrogen : Accelerate the development of the entire industry chain for green hydrogen—“ production, storage, transportation, and use ”—and build green hydrogen, green ammonia, and green methanol industry clusters; advance cross-provincial and cross-regional long-distance hydrogen-ammonia-methanol pipeline projects, and moderately make forward-looking arrangements for green hydrogen storage and transportation infrastructure. Leap in energy storage scale : Advance pumped-storage hydropower in stages, implement a special action for the large-scale development of new-type energy storage, and build a diversified energy storage system; by the end of the “15th Five-Year Plan” period, new-type ESS installations are expected to reach 60 million kW , and demand-side response capability is expected to exceed 5 of the region’s maximum load. Coordinated pipeline network upgrade : Optimize the oil and gas pipeline network; by the end of the “15th Five-Year Plan” period, natural gas pipeline mileage is expected to exceed 8,000 km , while the green hydrogen storage and transportation network will be improved in parallel. II. Rare Earth Industry: Extending, Supplementing, and Strengthening the Industry Chain, with a Focus on High-End Materials Such as Hydrogen Storage The Outline made clear to accelerate extending, supplementing, and strengthening the industry chain for the light rare earth industry , with a focus on developing: high-performance magnetic materials, high-performance polishing materials, hydrogen storage materials , catalytic materials and additives, rare earth steel, and other high-end rare earth new materials and end-use applications industries. Leveraging its advantages in rare earth resources, it will provide critical material support for industries such as hydrogen energy and new energy, and build a nationally leading base for rare earth new materials. III. Scientific and Technological Innovation: Focusing on Advantageous Fields Such as Green Hydrogen-Ammonia-Methanol The Outline proposed to implement a number of major science and technology tasks , focusing on fields including: new energy, rare earth new materials, carbon-based new materials, semiconductor new materials, green hydrogen-ammonia-methanol , biopharmaceuticals, biological breeding, and grassland and dairy industries, among others. It will deliver more landmark original achievements, providing technological support for the green hydrogen, green ammonia, and green methanol industries. IV. Significance of the Plan: Anchoring National Strategy and Leading the Energy Transition This plan closely integrates hydrogen energy, energy storage, rare earths, and green hydrogen-ammonia-methanol. It is not only a key measure to implement the country’s “dual carbon” goals, but also a core lever for Inner Mongolia to leverage its two major strengths in wind and solar power resources and rare earth resources and build a nationally important base for energy and strategic resources. As a number of wind and solar power-based hydrogen production projects, such as the Huadian Darhan Muminggan Banner project, advance, Inner Mongolia is accelerating its transformation from a major energy region into a leading green hydrogen region and an energy storage hub .

I. Coal-to-Hydrogen Shandong anthracite transaction range [1,710-1,710], average hydrogen cost [1.58 yuan/m³] Shanxi anthracite transaction range [910-910], average hydrogen cost [0.96 yuan/m³] Hebei anthracite transaction range [1,390-1,390], average hydrogen cost [1.33 yuan/m³] Henan anthracite transaction range [1,010-1,010], average hydrogen cost [1.05 yuan/m³] II. Natural Gas-to-Hydrogen Pearl River Delta natural gas transaction range [5,520-5,620], average hydrogen cost [2.62 yuan/m³] Zhejiang natural gas transaction range [5,470-5,800], average hydrogen cost [2.62 yuan/m³] Guangxi natural gas transaction range [5,570-5,990], average hydrogen cost [2.65 yuan/m³] Eastern Guangdong natural gas transaction range [5,500-5,590], average hydrogen cost [2.58 yuan/m³] Henan natural gas transaction range [4,540-4,780], average hydrogen cost [2.25 yuan/m³] Hebei natural gas transaction range [4,610-5,405], average hydrogen cost [2.37 yuan/m³] Hubei natural gas transaction range [5,060-5,910], average hydrogen cost [2.57 yuan/m³] Guizhou natural gas transaction range [5,080-5,660], average hydrogen cost [2.52 yuan/m³] Sichuan natural gas transaction range [5,025-5,325], average hydrogen cost [2.46 yuan/m³] Shanxi natural gas transaction range [4,500-4,700], average hydrogen cost [2.18 yuan/m³] Shandong natural gas transaction range [4,840-5,460], average hydrogen cost [2.45 yuan/m³] Heilongjiang natural gas transaction range [5,990-6,300], average hydrogen cost [2.83 yuan/m³] Inner Mongolia natural gas transaction range [4,620-4,890], average hydrogen cost [2.21 yuan/m³] III. Propane-to-Hydrogen South China propylene oxide transaction range [6,280-6,410], average hydrogen cost [3.62 yuan/m³] east China propylene oxide transaction range [6,390-7,190], average hydrogen cost [3.84 yuan/m³] Northeast China propylene oxide transaction range [6,170-6,720], average hydrogen cost [3.67 yuan/m³] Shandong propylene oxide transaction range [6,790-7,220], average hydrogen cost [3.97 yuan/m³] IV. Hydrogen Production from Methanol Methanol transaction range in east China [2,430-2,740], average hydrogen cost [2.32 yuan/m³] Methanol transaction range in central China [2,300-2,720], average hydrogen cost [2.3 yuan/m³] Methanol transaction range in north China [2,080-2,680], average hydrogen cost [2.15 yuan/m³] Methanol transaction range in south China [2,530-2,590], average hydrogen cost [2.29 yuan/m³] Methanol transaction range in northwest China [2,120-2,370], average hydrogen cost [2.04 yuan/m³] Methanol transaction range in southwest China [2,240-2,800], average hydrogen cost [2.31 yuan/m³] Methanol transaction range in northeast China [2,630-2,650], average hydrogen cost [2.35 yuan/m³]

The Netherlands generated 132 billion kWh of electricity in 2025, a 10% year-on-year increase, with renewables accounting for 49% of the total mix. Solar output surged 17%, driven by a sunny season and a 4% growth in installed capacity, which includes around 550 MW of small-scale PV added in the first half of the year. Conversely, fossil fuels supplied 48% of the total, as natural gas and coal generation rose by 11% and 25%, respectively. Bolstered by strong domestic production, the country's electricity exports jumped 25% to 30 billion kWh, heavily supplying neighboring Germany and Belgium amid regional generation shortfalls.

In the fields of precious and rare metals, compared with well-known categories such as gold, silver, and platinum-group metals, osmium has always remained a niche yet highly distinctive presence. With its unmatched physicochemical properties, it has become an indispensable key material in high-end industry and scientific research. Even though it receives limited market attention, it still possesses irreplaceable value. This article will provide a comprehensive breakdown of osmium metal, covering its basic properties, resource supply, application scenarios, and market characteristics, to offer a full understanding of this “king of density.” I. First Encounter with Osmium: A Hardcore Outlier Among the Platinum-Group Metals Osmium, with the chemical symbol Os and atomic number 76, belongs to the platinum-group metals. It is a Group VIII transition metal on the periodic table and also one of the rarest metals found in nature. As one of the six major members of the platinum-group metal family, osmium has no independent ore deposits and is commonly associated with platinum, iridium, ruthenium, rhodium, and palladium. It can only be recovered through purification during platinum ore smelting and cannot be extracted through standalone large-scale mining. This inherent characteristic directly defines its scarcity. Osmium’s physicochemical properties are truly unique in the world of metals, with highly recognizable core characteristics: first, it has the highest density in the world. Under standard conditions at 20°C, its density reaches 22.59 g/cm³, far exceeding that of gold (19.32 g/cm³) and platinum (21.45 g/cm³). It is currently the densest naturally occurring metal known, and at the same volume, it weighs far more than various conventional precious metals. Second, it demonstrates excellent high-temperature resistance, with a melting point of 3,033°C and a boiling point exceeding 5,000°C. It remains highly stable in high-temperature environments and can adapt to various industrial and scientific applications under extreme heat. Third, it has outstanding hardness and strong corrosion resistance. With a Mohs hardness of 7, it is hard, durable, and wear-resistant, and is difficult to corrode under conventional acidic or alkaline conditions. However, its drawbacks are also quite evident: it is highly brittle and has extremely poor plasticity, making it impossible to process through conventional mechanical methods, so it is mostly used in powder or alloy form. A key safety precaution must be emphasized here: when osmium metal is heated in air to above 100°C, it slowly oxidizes to form osmium tetroxide (OsO₄). This substance is highly irritating, highly volatile, and somewhat toxic. Therefore, the entire process involving osmium, including production smelting, storage and transportation, and deep processing, must be carried out under the protection of inert gas and in strict compliance with operational standards. These exceptionally high compliance and control requirements further raise the barriers to osmium’s production and application. II. Extreme Scarcity: Osmium’s Resource Endowment and Supply Landscape Osmium is far rarer than commonly recognized precious metals such as gold and platinum, and it can be regarded as a “niche treasure” in the precious metals sector. Relevant data show that the average abundance of osmium in the Earth’s crust is only about 0.001 ppm, making it one of the least abundant stable elements in the crust. Globally, identified recoverable reserves are extremely limited, and resource distribution is highly concentrated, without the formation of widely distributed ore deposits. Supply side further highlights the scarcity of osmium. As there are no standalone mines, global osmium production is entirely dependent on platinum mining and smelting, with capacity remaining at an extremely low level for many years. Global annual production is about 1 mt (data from the International Platinum Group Metals Association), while China’s annual production is less than 100 kg, with supply far below that of other platinum group metals. From the global supply landscape, traditional major platinum group metal-producing countries such as South Africa and Russia control the vast majority of the world’s osmium resources and smelting capacity. Industry supply is therefore highly monopolized, with extremely low supply elasticity. Minor changes in mine development progress, geopolitical conditions, environmental protection-related control policies, and platinum group metal smelting capacity all directly affect global osmium supply. This dual attribute of “inherent resource scarcity + constrained supply” has kept the osmium market in a long-term tight supply-demand balance and given it strong price resilience and fluctuation elasticity, securing it a unique position in the rare metals market. III. Exclusive to Cutting-Edge Applications: Core Application Scenarios for Osmium Although osmium has limited production and a relatively narrow application scope, its exceptional physical and chemical properties have enabled it to establish a precise foothold in high-end niche fields, making it an irreplaceable core material in many cutting-edge applications. Downstream demand is concentrated and highly rigid, with no low-cost substitutes currently available. Its core applications are mainly concentrated in four major areas: 1 Special Hard Alloys: Core Raw Materials for High-End Wear-Resistant Components Osmium-based alloys produced by melting osmium with metals such as iridium and platinum combine ultra-high hardness, wear resistance, and corrosion resistance, making them key materials for high-end precision instruments. These alloys are widely used in high-precision bearings for high-end watches and precision instruments, nibs for premium fountain pens, styluses for professional record players, and medical precision scalpels and wear-resistant components for high-end machinery. They can significantly extend service life and durability, making them suitable for long-term, high-load, high-wear operating environments, and they are core wear-resistant materials in high-end manufacturing. 2 Industrial Catalysis: Highly Efficient Specialized Additives for Fine Chemicals Osmium and its compounds have excellent catalytic activity and serve as specialized catalysts in certain fine chemical and organic synthesis reactions. In particular, in special chemical processes such as hydrogenation and oxidation reactions, they offer high catalytic efficiency and strong reaction selectivity, effectively optimizing process flows and improving product purity and yield. Although the unit consumption of osmium catalysts is extremely low, they are a rigid process necessity and are difficult to replace with other common metal catalysts, resulting in relatively stable downstream demand. 3 Scientific Research and Detection: Essential Specialized Consumables for Laboratories Although osmium tetroxide is toxic, it has irreplaceable value in scientific research. It is a high-quality staining agent for biological samples and microscopic material sections under electron microscopes, substantially improving sample clarity and contrast, and is an indispensable laboratory reagent in frontier research fields such as materials science and life sciences. Meanwhile, high-purity osmium powder was also widely used in high-end scientific research experiments and the R&D of specialized new materials, serving as a niche but essential consumable for major research institutes and high-end laboratories. 4. High-End Specialized Fields: Core Components for Military and Aerospace Applications Leveraging its core advantages of high density, high-temperature resistance, and high stability, osmium was also applied in specialized high-temperature components for aerospace and military applications, precision guidance components, as well as niche scenarios such as high-end electrical contacts and wear-resistant coatings. These applications were all concentrated in cutting-edge, high-precision sectors. Although the volume of each individual application was small, the product value-added was extremely high. Moreover, with the technological iteration and development of high-end manufacturing and the military and aerospace industries, related demand had the potential for steady growth. IV. Summary of the Core Characteristics of the Osmium Metal Market Overall, as a rare category among platinum group metals, osmium had highly distinctive core characteristics: extreme scarcity on the resource side, highly monopolized supply with insufficient elasticity; application-side concentration in high-precision, cutting-edge fields, with rigid and irreplaceable demand; and unique physicochemical properties, combining both advantages and application barriers. Unlike the market-driven fluctuation logic of conventional bulk commodities, the osmium market was significantly affected by factors such as supply-side changes, downstream demand from high-end industries, and compliance costs. The overall market size was small, and trading frequency was relatively low, placing it in the category of niche rare precious metals. Its core value always revolved around the two key points of “scarcity” and “irreplaceability,” making it an indispensable key metal material in high-end industrial and scientific research fields.

[SMM Tin Morning Briefing: The Most-Traded SHFE Tin Contract Opened Sharply Lower in the Night Session and Remained Rangebound at Low Levels, While Trading in the Spot Market Was Relatively Mediocre]

◼ At the beginning of 2026, Musk’s SpaceX plan for 100 GW of annual space PV capacity ignited the A-share market, with multiple concept stocks rising by more than 30 in a single month. At the same time, however, earnings previews from leading PV companies generally showed losses for 2025, and industry fundamentals remained in a deep winter. Behind the stark divergence between the speculative frenzy around the Musk-SpaceX concept and the earnings trough, is the market overly expecting a “second growth curve,” or is this a genuine signal of industrial transformation? ◼ As the global PV industry moves from rapid expansion into a new stage of rational development, its value has gone beyond that of clean energy alone: Against the backdrop of explosive growth in AI computing power driving massive electricity demand, compounded by energy security anxiety triggered by geopolitical conflict in the Middle East, developing PV may become a core strategic choice for countries to achieve their “dual-carbon” goals, build autonomous and controllable energy systems, and reduce electricity costs for end-users. ◼ Since the escalation of the U.S.-Iran conflict at the end of February, the world’s four major benchmark crude oil prices have entered a rapid upward trajectory. Before the outbreak of the conflict, oil prices had remained broadly stable; however, starting on March 2, as the fighting expanded and spread to the Persian Gulf, oil prices immediately entered a sharp uptrend. Note: Shanghai crude oil prices are converted based on the settlement-date exchange rate of 1:0.15. Source: Public information, SMM. ◼ Although the impact borne by different regions varies due to differences in energy mix, geopolitical location, and policy response, the surge in imported crude oil costs driving a broad rise in energy prices has become a common challenge facing all countries. Europe is a case in point. Although Europe’s direct dependence on Middle Eastern crude oil was not high, at only about 5 according to data from energy market intelligence firm Kpler, it remained highly dependent on the region for refined products such as diesel and aviation kerosene, as well as liquefied natural gas. Disruptions in the Strait of Hormuz caused by the conflict directly pushed up Europe’s terminal energy prices—fuel prices at gas stations across the region surged, and natural gas prices broke above EUR 60 per megawatt hour on the 9th, reaching a new high since 2022. The continued rise in energy prices is bound to transmit into broader areas of the economy, increasing overall inflationary pressure and once again underscoring the importance of building secure and controllable energy systems. Accelerating the Clean Transition of the Global Energy Mix, the PV Industry Advances Toward High-Quality Development ◼ The International Energy Agency (IEA) forecasts that, despite economic pressure, global electricity demand momentum remains strong in 2025, with growth rates in 2025 and 2026 expected to be 3.3% and 3.7%, respectively. Data from 2020 to 2025 showed that the global power market followed a trajectory of continued overall growth alongside structural transition toward cleaner energy , with the share of renewable energy sources such as solar rising significantly, although fossil fuels still accounted for the dominant share. ◼ According to the IEA’s Net Zero Emissions Scenario, solar power’s share in the energy mix is expected to rise from less than 2% at present to 12% in 2035 and 28% in 2050. This means PV installations are still far from reaching their ceiling, with substantial room for future growth. ◼ The past five years marked a critical period in which the global PV market shifted from rapid expansion toward rational development. The IEA forecasts that total global new PV installations over the next five years will reach about 3.68 TW, accounting for nearly 80% of new renewable energy additions over the same period, and are expected to become the world’s largest renewable energy source by the end of 2030. This is mainly due to its widening economic advantages—by 2024, the cost of solar PV power generation had already fallen 41% below the cheapest fossil fuel alternative, and these cost advantages are driving rapid growth in both PV installations and power generation share. Source: IEA, public information, SMM. ◼ As a key carrier of PV installations, especially the backbone of utility-scale power plants, solar panel mounting bracket installations are expected to maintain annual average growth of 5%-6% alongside installation growth. Specifically, to achieve annual average new PV installations of 500-600 GW, corresponding module demand is estimated at about 550-700 GW based on the capacity ratio. Assuming a conventional 1:1 module-to-bracket configuration, the annual average installation scale of brackets required for utility-scale PV plants alone would reach at least 250-300 GW. Source: public information, SMM. Escalating Challenges Reshape the Development Logic of the Global PV Market ◼ The PV industry is undergoing resonating internal and external pressures. Internally, the global economic slowdown has become intertwined with social issues, while the industry itself has entered a rational development stage after rapid expansion, making slower installation growth a certain trend. Externally, global trade frictions continue to intensify, with the US, Europe, and other regions erecting nearly insurmountable cost gaps through barriers such as anti-dumping and countervailing duties as well as local content requirements. Challenge 1: Global Trade Frictions and Escalating Trade Barriers ◼ In recent years, countries have introduced a series of policies to build PV trade barriers and reshape the global competitive landscape of the industry. The US imposed “double anti-” duties of as much as 3,403.96% on PV products from four Southeast Asian countries, South Africa raised module tariffs to 10%, and Brazil increased out-of-quota tariffs sharply from 9.6% to 25% through a quota system. Market access requirements for PV in India and Türkiye have also become increasingly stringent. Meanwhile, new supply chain control rules represented by the EU’s Net-Zero Industry Act (NZIA) have extended trade barriers deeper into the industry chain. By setting red lines on “third-country dependence,” they have established quantitative standards for supply chain restructuring. This series of changes has reshaped the competitive dimensions of the international PV industry and significantly raised the threshold for PV product imports and exports. Source: public information, SMM. Challenge 2: New Dynamics in the PV Market, with Incentive and Restrictive Policies Coexisting Source: public information, SMM. Outside China Enterprises Pursue Multi-Dimensional Breakthroughs Through Internal and External Efforts ◼ The practices of solar panel mounting bracket enterprises in the US, India, and other countries show that the key to coping with policy shifts overseas lies in combining “service-oriented” and “high-value” strategies. First, vertically extending from single-equipment sales to a service ecosystem covering the entire life cycle. Second, deepening horizontally by continuously optimizing business structure and extracting value from higher value-added segments. Solution 1: Launch Dedicated Plans Closely Aligned with Government Policies and Local Demand ◼ The global PV industry has now entered a new stage deeply reshaped by both market forces and policy. The growth logic of enterprises is shifting from the past single dimension of relying on technology iteration and cost declines to multi-dimensional competition closely integrating complex policy environments with localized demand. Against this backdrop, the key to corporate success lies in accurately interpreting policy intentions and launching development plans aligned with both market and policy. Tata Power Renewable Energy Limited (TPREL) precisely aligned with India’s “PM Surya Ghar: Muft Bijli Yojana” and launched the dedicated “solar for every home” plan while continuing to provide customized PV solutions. In Q1 FY2026, it added 220 MW of new rooftop PV installations, surging 416% YoY. TPREL also actively responded to local manufacturing policies by establishing 4.3 GW of solar cell and module capacity, ensuring supply while avoiding import tariffs. Through the synergy of “policy response + local capacity + customized services,” TPREL has effectively translated policy dividends into market competitiveness and steadily consolidated its leading position in India’s PV market. Solution 2: Use Acquisitions as a Link to Integrate Resources and Extend from Single Products to the Entire Industry Chain ◼ Competition in the global PV industry has fully escalated into a contest of entire industry chain system integration capabilities, and enterprises’ growth engines are shifting from past reliance on advantages in a single segment to a new model of providing integrated solutions through resource integration. In 2025, Nextracker used acquisitions as the core to integrate resources across the full chain, successively acquiring foundation engineering firms such as Solar Pile International and Ojjo, module supporting firms such as Origami Solar, and electrical system firms such as Bentek, thereby building a full-chain product matrix spanning structural, electrical, and digital solutions. Its performance continued to surge, with revenue rising from $1.9 billion in FY2023 to $3.4 billion in the trailing twelve months ended September 2025. It ultimately announced its transformation into a comprehensive energy solutions provider by renaming itself Nextpower, targeting revenue of more than $5.6 billion in FY2030. This strategy enabled its successful transformation from a single-product supplier into an entire industry chain service provider, solidifying its leading position in the global market. Solution 3: Optimize Business Structure ◼ Trade protectionism in the current PV market continues to intensify, with various trade barriers being layered on one after another. In response to this challenge, PV enterprises can achieve the dual objectives of “compliant operations” and “market retention” through business structure optimization. To avoid the equity constraints on FEOC under the US OBBB Act, Canadian Solar Inc. initiated a US business restructuring with its controlling shareholder CSIQ: it established two new joint ventures to separately manage PV and energy storage businesses, with its own stake set at 24.9% to precisely meet compliance requirements. At the same time, it transferred out 75.1% equity in three overseas plants supplying the US market, receiving a one-off consideration of 352 million yuan. This move enabled Canadian Solar Inc. to retain earnings from the US market through dividends and rental income. In the first three quarters of 2025, it achieved net profit of 990 million yuan, while large-scale energy storage shipments rose 32% YoY. After the adjustment, it focused on strengthening its advantages in non-US markets and successfully stabilized its global business layout with a compliant structure, providing a typical model for the industry in addressing trade barriers. ◼ For Chinese enterprises, in the face of trade frictions and overseas capacity gaps, they need to break through via three paths—“building plants near core markets, reducing costs and improving efficiency through technological innovation, and coordinating both within and outside the industry chain”— by pursuing localized deployment in Southeast Asia, Mexico, and other regions to avoid frequent trade frictions; promoting standardized production and high-end product R&D to enhance competitiveness; and building a “China + overseas” dual-circulation supply chain to stabilize costs. However, overseas expansion still faces challenges such as land and environmental protection costs, talent shortages, and supply chain fluctuations, requiring enterprises to conduct sound risk assessments, leverage policy support, and improve overseas investment service systems. Only by deeply integrating scientific capacity deployment, technological innovation, and industry chain coordination can the mounting bracket industry upgrade from “Made in China” to “Globally Intelligent Manufacturing” and achieve long-term development under the “dual carbon” goals. New Requirements Under the 15th Five-Year Plan, New Topics for PV Enterprises ◼ In a global market full of uncertainties, the consistency and strength of domestic policy have provided fertile ground for the growth of China’s solar panel mounting bracket enterprises. The newly released 15th Five-Year Plan further clarified China’s path for energy and industrial development. On the one hand, the construction of a new-type power system centered on consumption capacity has been listed as a priority task, and green manufacturing and full life cycle management have been formally incorporated into the assessment system. On the other hand, technological self-reliance and self-strengthening together with new quality productive forces have replaced scale competition as the main line of the new development stage. This series of changes signals that the country is driving a profound shift from “competing on capacity” to “competing on system value,” with the core goal of achieving autonomous and controllable energy structure. It is estimated that after the Two Sessions, various departments will successively roll out detailed plans to promote the full implementation of the blueprint. ◼ Key implementation measures include: 1) establishing a “dual controls” system for total carbon emissions and carbon intensity, while improving incentive and restraint mechanisms; 2) vigorously developing non-fossil energy and promoting the efficient use of fossil energy, while strengthening the construction of a new-type power system to ensure stable supply of green electricity; 3) applying both “addition and subtraction” by fostering green and low-carbon industries and promoting energy conservation and carbon reduction in key industry; 4) in addition, accelerating the green transformation of production and lifestyles to consolidate the foundation for green development. ◼ From the perspective of regional development layout, during the 15th Five-Year Plan period, China’s PV industry will show characteristics of regional coordination: north-west China will become the strategic focus by virtue of its natural endowments, exporting electricity through cross-provincial green electricity trading and other means to achieve two-way matching between energy resources and power load; eastern regions, by contrast, will focus on local consumption by high-energy-consuming industries and zero-carbon industrial parks. Source: public information, SMM. ◼ SMM forecasts that China’s new PV installations are expected to reach 208 GW in 2025 and continue growing at an annual average rate of 9% over the next five years, exceeding 292 GW by the end of the 15th Five-Year Plan period. Utility-scale PV will remain dominant, with its installation share staying above 50%. Based on the same logic, we estimate that China’s PV installation market will maintain annual incremental growth of at least 100-120 GW. Source: public information, SMM. ◼ Focusing on China’s steel consumption market for solar panel mounting brackets, SMM estimates that annual steel consumption in China’s PV mounting bracket sector will average about 4-4.5 million mt from 2026 to 2030, accounting for about 30% of total steel consumption in the PV industry over the same period (based on 2026 data). Note: only installation demand for utility-scale PV mounting brackets is included, excluding distributed steel structures, replacement from existing asset depreciation, and exports. Source: public information, SMM. SMM Ferrous Consulting Based on its understanding of the global steel industry chain and regional markets, as well as its strong industry database and network resources, SMM is committed to providing clients with consulting services across the upstream, midstream, and downstream industry chain. Services include market supply and demand research and forecasts, market entry strategies, competitor cost research, and more, covering end-use industry from iron ore, coal, coke, and steel. SMM Ferrous has successfully served more than 300 Fortune Global 500 companies, China Top 500 companies, central state-owned enterprises, state-owned enterprises, publicly listed firms, and start-ups. Data Source Statement: Except for public information, all other data are processed and derived by SMM based on public information, market communication, and SMM’s internal database models, and are for reference only and do not constitute decision-making advice. *This report is an original work and/or compilation work exclusively created by SMM Information & Technology Co., Ltd. (hereinafter referred to as “SMM”), over which SMM lawfully enjoys copyright, protected by the Copyright Law of the People’s Republic of China and other applicable laws, regulations, and international treaties. Without written permission, it may not be reproduced, modified, sold, transferred, displayed, translated, compiled, disseminated, or otherwise disclosed to any third party or licensed to any third party for use in any form. Otherwise, upon discovery, SMM will pursue legal liability for infringement by legal means, including but not limited to claims for breach of contract liability, disgorgement of unjust enrichment, and compensation for direct and indirect economic losses. All content contained in this report, including but not limited to news, articles, data, charts, images, audio, video, logos, advertisements, trademarks, trade names, domain names, layout designs, and any or all other information, is protected by the Copyright Law of the People's Republic of China, the Trademark Law of the People's Republic of China, the Anti-Unfair Competition Law of the People's Republic of China, and other relevant laws and regulations, as well as applicable international treaties relating to copyright, trademark rights, domain name rights, proprietary rights in commercial data and information, and other rights, and is owned or held by SMM and its relevant rights holders. Without prior written permission, no organization or individual may reproduce, modify, use, sell, transfer, display, translate, compile, disseminate, or otherwise disclose the above content to any third party or permit any third party to use it in any form whatsoever. Otherwise, upon discovery, SMM will pursue legal action to hold the infringing party liable, including but not limited to requiring the assumption of liability for breach of contract, disgorgement of unjust enrichment, and compensation for direct and indirect economic losses. The English translation of the above text is:

Germany fed 438.2 TWh into its public grid in 2025. While solar generation surged 17.4% to a record 70.1 TWh (nearly tying with natural gas), overall renewable output dipped slightly, reducing its grid share to 58.6%. Wind remained the top energy source despite a 3.6% drop to 131.3 TWh. Conversely, fossil fuel generation increased to a 41.4% share, largely driven by a 10.2% jump in gas-fired output. Germany also narrowed its net electricity import surplus to 19.4 TWh.

On March 9, the New Product Launch Conference for the Sixth Academy of the Aerospace Science and Technology Corporation’s hydrogen energy industry was held in Beijing, where four core achievements were unveiled on site: the side-mounted 2×40 kg-class onboard liquid hydrogen system (Saidao-1000S), a mobile liquid hydrogen refueling skid and hydrogen dispenser, a 40-foot liquid hydrogen tank container, and a 200-cubic-meter innovative alkaline electrolyzer . The Blue Book on the hydrogen energy industry was also officially released. The conference brought together academicians, ministry officials, representatives from government, enterprises, universities, and the industry chain, marking the Sixth Academy’s liquid hydrogen equipment portfolio as having fully entered a new stage of commercial application. High-Level Participation to Jointly Discuss a New Blueprint for the Hydrogen Energy Industry The conference featured a high-profile lineup, with three academicians—Long Lehao, Yang Fengtian, and Wang Jue—in attendance, along with relevant officials from the State Administration for Market Regulation and the National Energy Administration; leaders from the Aerospace Science and Technology Corporation and affiliated enterprises also attended, including Li Zhongbao, Chief Engineer of the Aerospace Science and Technology Corporation, Xie Yun, Chairman of Aerospace Investment, and Wang Wanjun, President of the Sixth Academy. Supervisory government authorities from multiple regions, experts from renowned universities, executives from central state-owned enterprises such as Sinopec, China Huadian, and FAW, as well as capital-side representatives from numerous hydrogen energy enterprises gathered together to witness the commercialization of aerospace hydrogen energy achievements. Praise From Academicians and Remarks by Senior Executives Highlight Aerospace Hydrogen Energy’s Leadership Academician Long Lehao congratulated the launch of the new products, noting that this represented a milestone breakthrough in China’s cryogenic liquefaction and hydrogen energy equipment fields, opening a pathway for aerospace hydrogen energy to serve the national economy and aligning with the national “dual carbon” and energy security strategies. Li Zhongbao, Chief Engineer of the Aerospace Science and Technology Corporation, stated that the Group regarded hydrogen energy as a strategic growth pole and would work with all parties to build a collaborative and shared industrial ecosystem and promote deep integration across the industry chain. Wang Wanjun, President of the Sixth Academy, said that the Academy adhered to the philosophy of “users first, power first,” and that multiple hydrogen energy equipment products had reached internationally advanced levels. In the future, it would accelerate technological iteration, improve the standards system, and make every effort to achieve the goal of bringing liquid hydrogen technology to the pinnacle. Four Powerful New Products Cover the Full Range of Production, Storage, Transportation, and Refueling Scenarios 1 Side-Mounted 2×40 kg-Class Onboard Liquid Hydrogen System (Saidao-1000S) China’s first subcooled liquid hydrogen system installed on a vehicle, it pioneered dual-cylinder coordinated liquid supply technology and delivered a driving range of over 1,000 kilometers at full load. It adopted an integrated chassis design to reduce wind resistance and release front-end space, and has already been demonstrated jointly with Foton Motor, making it suitable for the large-scale application of liquid hydrogen heavy trucks. 2 Mobile Liquid Hydrogen Refueling Skid and Liquid Hydrogen Hydrogen Dispenser China’s first mobile refueling system for subcooled liquid hydrogen, it fills the gap in temporary refueling for non-fixed stations. By achieving breakthroughs in core technologies, it delivers a liquid hydrogen utilization rate of over 95%, a refueling flow rate of 15 kg/min, and completes full-tank refueling for a heavy truck in 15 minutes, with performance comparable to world-class international standards. 3. 40-Foot Liquid Hydrogen Tank Container The first standardized liquid hydrogen storage and transport equipment, compatible with global road and maritime logistics, with the transport radius extended to over 2,000 kilometers and unit costs reduced by 50% compared with high-pressure gaseous hydrogen. The daily evaporation rate was 0.52% and could be maintained for more than 8 days, addressing the pain points of low storage and transport volume and high costs. 4. 200 m³ Innovative Alkaline Electrolyzer Built on aerospace technology, with direct current (DC) power consumption as low as 4.1 kWh/Nm³, reaching the national Grade 1 energy efficiency standard; the modular design reduced operation and maintenance costs by 90%, supported 12-hour rapid on-site repair, and met the needs of green hydrogen production in multiple scenarios.