According to a post on TeslaAI's Weibo account, the TERAFAB project was officially launched and is expected to achieve computing power output of more than 1 terawatt (1 TW) per year. Musk predicts that the humanoid robot industry could potentially reach an annual production volume of 1 billion to 10 billion units in the future. As robots enter a stage of larger-scale deployment, demand for high-performance chips will further increase. TERAFAB will produce chips for Tesla's humanoid robots.

◼ 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. 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Recently, the European hydrogen equipment giant Hexagon Purus officially announced the sale of 100% equity in the aerospace business of its subsidiary Hexagon Masterworks Inc. (abbreviated as "Masterworks") to the commercial space giant SpaceX, owned by Elon Musk, for approximately $15 million. This transaction signifies Hexagon Purus's further focus on its core hydrogen energy business, while SpaceX strengthens its layout in key segments of the space supply chain. The transaction amount is clearly detailed, totaling approximately $15 million, and is specifically composed of two parts: first, upon completion of the closing, SpaceX will pay $12.5 million in cash; second, the remaining $2.5 million will be paid in cash or cash equivalents, subject to applicable closing conditions and industry practices. It is understood that Masterworks's core business focuses on the R&D and manufacturing of high-pressure composite gas cylinders for the aerospace sector, while also engaging in hydrogen energy vehicle-related products in the North American market, with mature expertise in high-pressure composite technology. Hexagon Purus explicitly stated that to protect the interests of hydrogen energy business clients, all existing hydrogen energy client contracts of Masterworks will be gradually transferred to other hydrogen energy-related business units under Hexagon Purus before the transaction is completed, ensuring smooth business transition without affecting client cooperation and performance. As a globally leading hydrogen energy equipment enterprise, Hexagon Purus's core development focus is to achieve zero-emission mobility and build a cleaner energy future. Its core products include Type IV high-pressure hydrogen cylinders and systems, battery systems, as well as vehicle integration solutions for fuel cell EVs and pure EVs. These are widely applied across various scenarios, covering light-duty, medium-duty, and heavy-duty vehicles, buses, ground energy storage, hydrogen distribution, hydrogen refueling stations, maritime, railway, and aerospace sectors. The sale of Masterworks's aerospace business is a key measure by Hexagon Purus to advance its portfolio optimization. It aims to divest non-core assets, improve financial conditions, extend cash flow sustainability, and concentrate more resources on core strategic directions such as high-pressure hydrogen storage tanks and hydrogen system integration, further consolidating its leadership in the global zero-emission mobility solutions sector. For SpaceX, Masterworks's high-pressure composite gas cylinder technology precisely meets its urgent need for high-performance, lightweight high-pressure tanks in the development of large launch vehicles like Starship and future space systems. This acquisition will help SpaceX enhance its vertical integration capabilities in the space supply chain and reduce dependence on external suppliers.

[SMM Analysis: Space PV Stimulates Market Sentiment to Heat Up, Yet the Path to PV Commercialization Remains Long] On January 22, Musk strongly endorsed space PV during the World Economic Forum annual meeting in Davos, Switzerland, and disclosed key capacity plans. Musk stated that SpaceX and Tesla are simultaneously advancing solar capacity expansion, aiming to achieve an annual solar manufacturing capacity of 100 GW within the next three years to power ground-based data centers and space AI satellites. Following the earlier visit by Musk's SpaceX team to China to meet with Chinese PV enterprises, market sentiment in the PV sector further rose.

Tesla Vice President Tao Lin stated today that Tesla would actively participate in related work on assisted autonomous driving in the Chinese market, but could not yet provide a clear timeline for implementation. Elon Musk previously indicated that Tesla's Full Self-Driving (FSD) would be deployed in Europe this February, with the Chinese market to follow.

This week (January 30 to February 5, 2026), the scaling of Tesla’s dry electrode process represented a revolutionary breakthrough in manufacturing, while Light-Year Engine’s “launch-to-production” approach marked a bold declaration on the product front. Both point to the core challenges of industrialisation —engineering and cost.