Recent Performance of Key Iron Ore Price Spreads Since 2024, large-scale iron ore projects in and outside China have been continuously commissioned, leading to a notable increase in iron ore supply. However, the sharp decline in downstream steel demand caused the iron ore supply-demand gap to widen continuously. The iron ore supply-demand pattern shifted from tight to loose, which also led to a year-on-year decline in average iron ore prices. Nevertheless, influenced by multiple factors such as iron ore supply and demand, port inventory, and steel mill profits, the frequency of price spread fluctuations among iron ore varieties increased. SMM reviewed the recent trends of key price spreads, as detailed below: ◼ Internal Differentiation Among Medium-Grade Resources, with Price Spreads Widening Significantly Affected by long-term contract negotiations, the trade liquidity of mainstream medium-grade ore deteriorated significantly. The lack of trade liquidity in certain varieties was directly transmitted to variety price spreads, with price spread fluctuations of mainstream medium-grade ore such as MNPJ intensifying notably. Among them, the price spread between PB fines and Jimblebar fines was the most sensitive: In early September 2025, the price spread between the two was 20 yuan/mt. As news of the ban on Jimblebar fines port cargo pick-up was released, its spot price came under pressure and dropped sharply, with the price spread quickly widening to around 50 yuan/mt. In addition, affected by the reduction in tradable varieties of mainstream Australian medium-grade ore, the variety price spreads between PB fines and Newman fines, as well as MAC fines, also showed a notable narrowing trend. Source: SMM ◼ High-Grade Premium Highlighted, Price Difference Between High and Medium-Grade Ore Widening Rapidly From Q4 2025 to date, price spread fluctuations among high, medium, and low-grade ore were equally intense. After entering 2026, structural contradictions in the iron ore market became further pronounced. Affected by declining raw ore quality from northern Brazilian mining areas, IOCJ fines supply experienced a trend of contraction. Coupled with the cost-effectiveness recovery brought by earlier price weakness and the release of concentrated restocking demand from steel mills ahead of Chinese New Year, IOCJ fines prices received strong support. Meanwhile, mainstream medium-grade ore remained tight in available resources due to trade flow disruptions. Against the backdrop of a shift between high and low-grade resources, the price difference between high and medium-grade ore widened again. Reviewing the period from November 2025 to March 2026, north China entered the heating season, and environmental protection-driven production restrictions became more frequent. As Chinese New Year and the Two Sessions approached, production restrictions were further tightened, with blast furnaces at steel mills in multiple areas of Hebei shut down, leading to a notable decline in hot metal production. Notably, during this period, steel mill profits remained generally stable, and some enterprises, in pursuit of higher output, tended to increase the blast furnace blending ratio of high and medium-grade ore while correspondingly reducing procurement of low-grade ore. Driven by this structural demand shift, the price difference between medium and low-grade ore widened. Source: SMM ◼ Lump-Fines Price Spread Experienced a "V"-Shaped Trend, Declining First Then Rising Since sintering processes generate relatively high pollution emissions, environmental protection-driven production restrictions typically prioritized restricting sintering and shaft furnace production. In north China and north-east China, during heating seasons or major events, if production restriction periods are prolonged, steel mills often increase the proportion of lump ore in their mix to alleviate tight supply of sinter and pellet, thereby driving lump ore prices to rise rapidly. However, over the past three years, the impact of seasonal factors on lump ore demand has gradually weakened, mainly for three reasons: first, steel mills have successively completed ultra-low emission retrofits for flue gas, reducing overall pollution intensity; second, sintering machines in Hebei and other regions have surplus capacity, and environmental protection-driven production restrictions have mostly been limited to within one week, significantly reducing the actual impact on production; third, steel mill profits have been under pressure, reducing the pursuit of hot metal production, and the proportion of high-grade ore usage has adjusted downward accordingly. Under the combined influence of the above factors, since H2 2024, lump ore premiums have continued to decline, hitting a new low by the end of 2025. Meanwhile, the price spread between PB lump and PB fines also narrowed significantly, contracting from 195 yuan/mt to 63 yuan/mt, a decline of over 50%. Against this backdrop, the cost-effectiveness of lump ore gradually became more prominent. Combined with the extended environmental protection-driven production restriction period in northern China in November 2025, the proportion of lump ore usage began to increase. However, as lump ore premiums had remained low for an extended period, product returns were poor, and major mines correspondingly reduced lump ore production. Driven by both supply contraction and demand growth, lump ore premiums rebounded, and the lump-fines price spread widened accordingly. As of mid-March 2026, lump ore premiums have risen to a periodic high, up nearly 280% from early January. The lump-fines price spread has also gradually widened to above 100 yuan/mt. Source: SMM Key Driving Logic of Product Price Spreads Mix Adjustment Led by Steel Mill Profits (Core Driver) ◼ 1 Profit Expansion Phase: High Hot Metal Production Drives Demand for High-Grade Ore When steel mill profits widened and per-mt crude steel returns were higher, steel mills pursued pig iron production and tended to raise the grade of furnace feed. When selecting iron ore, they preferred to purchase high-grade or medium-grade ore. As shown, in H1 2025, profits of common billet at China's steel mills rebounded notably. Common billet profits reached a peak of nearly 350 yuan/mt. At this point, to boost production, steel mills moderately increased the proportion of high-grade IOCJ fines, as well as high-grade lump and pellet usage. Demand growth over a certain period stimulated high-grade ore price increases, and it was clearly evident that the price spread between high-grade and medium-grade ore began to widen. Source: SMM ◼ 2 Profit Contraction Phase: Cost Reduction and Efficiency Improvement Boost Low-Grade Ore Procurement After steel mill profits contracted, to reduce costs and improve efficiency, steel mills significantly increased their focus on cost-effectiveness across iron ore products, tending to prioritize products with higher cost-effectiveness. Within the mid-grade ore range, steel mills preferred varieties with a larger price spread relative to PB fines. Meanwhile, weakening profits meant that higher pig iron or crude steel production led to greater loss pressure. Therefore, steel mills controlled pig iron production rationally from the perspective of economic efficiency. However, given the high comprehensive costs of shutting down or reducing blast furnace loads, steel mills tended to maintain normal blast furnace operations while lowering furnace charge grade and increasing the use of low-grade ore. Under these circumstances, assuming other conditions remained unchanged, the price spread between mid- and low-grade ore tended to narrow. Taking the market around October 2025 as an example, billet profits continued to decline, and the mid-to-low-grade ore price spread narrowed accordingly. Data source: SMM Dual Transmission Paths of Seasonal Effects ◼ Seasonal factors influenced iron ore variety demand through dual paths of "end-use demand fluctuations" and "heating season environmental protection-driven production restrictions" ◼ 1. Seasonal fluctuations in end-use demand: impact on steel mill production and raw material procurement pace The shift between off-season and peak season in end-use demand created cyclical impacts on iron ore variety demand. Off-seasons were mainly concentrated in summer (June–August) and winter (November–February): high temperatures and heavy rainfall in summer suppressed construction, while hydropower replacing thermal power in south China lowered electric furnace production costs and squeezed blast furnace hot metal production; in winter, construction sites in north China shut down and steel demand contracted. During off-seasons, steel mills increased blast furnace maintenance and lowered furnace charge grade to control production, with demand for high-grade iron ore weakening accordingly. During peak seasons (spring March–May, autumn September–October), downstream construction activity was released intensively, steel mills actively ramped up production, and furnace charge grade rose in tandem, strengthening demand for high-grade fines, lump ore, and pellet, supporting their premium performance. In summary, seasonal fluctuations in end-use demand drove cyclical changes in iron ore variety demand by influencing steel mill production and furnace charge grade selection. Transmission logic: end-use demand fluctuations → steel mill production adjustments → changes in total iron ore procurement volume → corresponding shifts in variety demand structure Data source: SMM Data source: SMM ◼ 2. Environmental protection-driven production restrictions during the northern heating season: direct disruption to furnace charge structure and variety premiums Heating season environmental protection-driven production restrictions primarily targeted steel mills in north China, spanning November to April of the following year . During this period, if air quality failed to meet standards, local environmental protection authorities would initiate production restriction measures, prioritizing restrictions on sintering machines and shaft furnaces, leading to tighter supply of sinter and pellet. To maintain blast furnace operations, steel mills were forced to increase the proportion of lump ore in their charge mix, driving a seasonal strengthening of lump ore demand, which in turn supported lump ore premiums and a rise in the lump-fines price spread. Transmission logic: environmental protection policy → sinter machine production restrictions → forced adjustment of furnace charge structure → stronger demand for lump ore and pellet ore → premium fluctuations Data source: SMM Coke prices affected the iron ore product mix through dual channels of fuel costs and profit margins ◼ 1 High coke prices suppressed lump ore demand As raw material directly charged into furnaces, lump ore consumed more coke than sinter and pellet ore, so steel mills typically controlled the lump ore charging ratio at around 10%. During periods when coke prices fluctuated at highs, steel mills tended to reduce lump ore proportions to control fuel costs. Before H1 2024, coke prices fluctuated at highs, and the lump ore usage ratio continued to decline, falling to a low of 9.8%. However, as coke prices underwent nearly a year of decline and entered a low range, combined with relatively low lump ore premiums and the push from environmental protection-driven production restriction policies, the lump ore charging ratio gradually rebounded, once exceeding 11%. Data source: SMM ◼ 2 Demand for high-silicon fines suppressed The higher the silicon content in iron ore, the greater the blast furnace slag volume and the higher the coke ratio. Therefore, low-silicon smelting is a key direction for blast furnace process optimization and a critical lever for cost reduction and efficiency improvement. Among current iron ore products on the market, mainstream mid-grade ore Si content mostly ranges from 4-6%. Brazilian high-silicon BRBF has relatively high Si content at 10-12%. Therefore, Australian ore is mostly used as the primary material, while Brazilian ore and non-mainstream ore serve as auxiliary materials. When coke prices were at highs, the cost disadvantage of high-silicon resources became prominent, and steel mills tended to reduce Brazilian high-silicon BRBF, Indian fines, and South African fines, shifting to mid-to-high-grade fines with lower silicon content (such as PB fines and IOCJ fines). Going forward, the iron ore oversupply pattern will become more prominent, while under overcapacity pressure in China's steel sector, steel mill profits will remain poor. Therefore, cost reduction and efficiency improvement will be a long-term direction, driving stronger demand for low-silicon, low-aluminum products. Consequently, mainstream mid-grade ore will remain the product with the best market circulation. Data source: SMM ◼ 3 Rising share of mid-to-low-grade fines under low profits High coke and ore prices squeezed steel mill profits, and steel mills no longer pursued hot metal production maximization, instead increasing mid-to-low-grade fines usage and lowering charging grade to control costs. Based on historical data, such situations occurred in Q3 2024 and Q2 2025. Auxiliary Variables: Inventory, Substitution, and Preferences ◼ 1 Product substitution effect: mid-grade inter-substitution and "high-low blending" substitution In the product mix of steel mill sinter, "high-low blending" and "mid-grade blending" are commonly mentioned concepts, with the core principle being to select the optimal products based on the cost-effectiveness of different iron ore varieties. Under normal circumstances, steel mills use MNPJ (i.e., mainstream medium-grade ore types such as Mac fines, Newman fines, PB fines, and Jimblebar fines) as primary materials, or adopt a high-low grade combination of " IOCJ fines + super special fines " as primary materials, and adjust auxiliary material ratios based on the acidity and alkalinity of the primary materials. Using mainstream medium-grade ore types as primary materials is the more common practice. When mainstream medium-grade ore types are periodically less cost-effective — for example, when the combined cost of "IOCJ fines + super special fines" is lower than that of medium-grade PB fines — some steel mills periodically switch to high-low grade combinations as primary materials to reduce costs. As shown in the chart, during March to April of 2024 and 2025, the cost-effectiveness advantage of high-low grade combinations was significantly superior to that of medium-grade ore, and therefore some steel mills in regions such as Hebei and Shanxi predominantly chose high-low grade combinations as primary materials during these periods. Data source: SMM ◼ 2. Inventory Structure Drives Price Spreads among Varieties: Inventory Changes and Price Transmission Logic Inventory is the most intuitive reflection of short-term supply-demand imbalances in the iron ore market. When supply is loose or demand weakens, port inventory continues to rise, and inventory levels generally exhibit a negative correlation with prices. Once inventory accumulates to a certain level, it tends to exert significant downward pressure on prices. Over the past two years, the inventory and price trends of Ukrainian concentrate (hereinafter "Ukrainian concentrate") have well validated this pattern. In November 2023, Ukrainian concentrate shipments gradually resumed, but as steel mills still had concerns about the stability of its supply, actual usage did not increase significantly, leading to continued port inventory accumulation. By May 2024, SMM ten-port inventory data by variety showed that Ukrainian concentrate inventory exceeded 3 million mt , exerting significant downward pressure on prices, with Ukrainian concentrate prices falling from 1,200 yuan/mt at the beginning of the year to 900 yuan/mt. Meanwhile, the price spread between Ukrainian concentrate and PB fines also narrowed from 160 yuan/mt to 80 yuan/mt, and its cost-effectiveness advantage gradually emerged, driving a notable increase in steel mill demand. Entering early 2026, affected by a decline in Ukrainian concentrate supply, port inventory retreated from highs to around 1.1 million mt, and tightening supply supported a notable rebound in Ukrainian concentrate prices, with the price spread versus PB fines also widening from 80 yuan/mt to around 100 yuan/mt . Data source: SMM Variety Cost-Effectiveness Assessment Model and Selection Strategy ◼ 1. Horizontal Comparison: Micro-Indicator Assessment among Same-Grade Varieties. In recent years, global mainstream iron ore supply entered a resource transition period, with notable structural adjustment characteristics. On one hand, some aging mines faced resource depletion , with declining mining grades; on the other hand, new mines were still in the capacity ramp-up stage , and the transition between old and new resources still required time. As a result, quality indicators of multiple mainstream varieties were broadly downgraded. Among them, medium-grade ore indicators represented by PB fines and Newman fines weakened; due to declining raw ore quality in Brazil's northern system, not only did IOCJ fines production contract, but the proportion of high-silicon special IOCJ fines output also rose, with silicon content increase being particularly notable beyond the decline in iron grade. Against this backdrop, steel mills tended to assess the most cost-effective varieties by calculating comprehensive price spreads. From the perspective of minor indicator adjustment values, the smaller the adjusted price spread relative to the MMI 61% index, the better the variety met steel mill demand. Based on Q1 averages, Jimblebar fines offered the best cost-effectiveness, followed by PB fines, Mac fines, Newman fines, and BRBR. However, since Jimblebar fines could not be traded or delivered, PB fines remained the optimal choice among medium-grade ores. Data source: SMM ◼ 2. Vertical Comparison: Historical Percentile Timing of High, Medium, and Low-Grade Price Spreads Beyond the horizontal comparison of price spreads among varieties of similar grades, vertically examining price spread changes among high, medium, and low-grade ores was equally important. By analyzing historical percentiles of the price difference between high and medium-grade ore and the price difference between medium and low-grade ore, the relative valuation of each grade could be assessed to guide variety switching and timing. Price difference between high and medium-grade ore: when at historical highs, the high-grade premium was excessive, and switching to medium-grade was advisable under profit pressure; when at historical lows, high-grade cost-effectiveness stood out, and moderate allocation increases were appropriate. Beyond premiums, using IOCJ fines and PB fines as benchmarks and calculating based on their indicator costs, the neutral value of the price spread between the two was 100 yuan/mt. When the spread exceeded 100 yuan/mt, PB fines offered better cost-effectiveness; when below 100 yuan/mt, IOCJ fines were more cost-effective. Price difference between medium and low-grade ore: when at historical highs, low-grade advantages were evident, suitable for cost reduction during thin-margin periods; when at historical lows, medium-grade cost-effectiveness improved, allowing flexible adjustments. Using PB fines and SSF as benchmarks and calculating based on their indicator costs, the price spread between the two ranged from 100-120 yuan/mt, with a midpoint of 110 as the neutral value. When the spread exceeded 110 yuan/mt, super special fines offered better cost-effectiveness; when below 110 yuan/mt, PB fines were more cost-effective. Combining the historical percentiles of both, allocation windows for each grade could be captured based on profit cycles to achieve cost optimization. Data source: SMM ◼ 3 Morphology Comparison: Arbitrage Logic of Fines-Lump Price Spread and Lump Ore Premium. Taking the price spread between PB lump and PB fines as an example, influenced by steel mill profits and coke prices, the fines-lump price spread exhibited notable fluctuations. Historical data showed the price spread between PB lump and PB fines ranged approximately 80–500 yuan/mt. In H1 2021, driven by high steel mill profits and supply-demand mismatch, the fines-lump price spread once approached the historical high of nearly 500 yuan/mt. In recent years, as steel mill profits narrowed, the price spread contracted significantly. In 2025, the fines-lump price spread operated within a range of 70–220 yuan/mt, with an annual average of approximately 128 yuan/mt. In early 2026, the lump ore premium fell to $0.04/dmt, and the price spread narrowed to 65 yuan/mt. Given that China's overcapacity landscape has not fundamentally changed, steel mill profits are expected to remain basically flat with 2025, and the fines-lump price spread is likely to maintain the current range. Based on this assessment: When the lump-fines price spread exceeds 120 yuan/mt, PB fines offer better value; When the lump-fines price spread falls below 120 yuan/mt, PB lump offers better value. Steel mills can choose accordingly based on their own conditions. Data source: SMM ◼ 4 Substitution Comparison: Cost-Effectiveness Competition between Lump Ore and Pellet Generally, when steel mill profits are favourable, steel mills consider increasing the usage ratio of lump ore and pellet. Typically, the combined usage share of lump ore and pellet ranges between 20%–30%. In actual ore blending decisions, steel mills' price spread analysis between lump ore and pellet falls into two categories: inland steel mills usually compare the price spread between domestic pellet and lump ore such as PB lump and Newman lump; while coastal port steel mills focus more on the price spread between imported pellet and corresponding lump ore. In recent years, with the increase in China's pellet capacity and the decline in imported pellet volumes, the weighting of price spread comparison between same-grade lump ore and domestic pellet has further increased. Historical data showed the price spread between 62% grade pellet in Qingdao and PB lump ore at Qingdao port ranged approximately 40–260 yuan/mt, with an annual average price spread of approximately 108 yuan/mt in 2025. Considering steel mills' actual cost accounting, the price spread equilibrium point between pellet and lump ore is generally set at 120 yuan/mt. When the pellet-lump price spread exceeds 120 yuan/mt, lump ore offers better value; When the pellet-lump price spread falls below 120 yuan/mt, pellet offers better value. Steel mills can choose accordingly based on their own raw material conditions, logistics structure, and production requirements. Data source: SMM Carbon Neutrality as a Two-Way Driver: Steel Industry Restructuring Shifts Iron Ore Demand ◼ The rapid advancement of industrialisation has significantly intensified the impact on the global climate, making the urgency of achieving carbon neutrality increasingly pressing. Particularly over the past five years, major economies represented by China and the EU have not only defined their respective emission reduction targets but also successively introduced legally binding regulations, marking a shift in global climate governance from consensus to action. Going forward, China's Ecological Environment Code and the EU's European Climate Law and "Fit for 55" package will become the two major institutional benchmarks for global climate governance. China's carbon market and the EU's CBAM, from the two dimensions of domestic carbon pricing and cross-border carbon adjustment respectively, form core policy tools for effectively controlling carbon emissions. Source: SMM ◼ Driven by both domestic and international legislation, the steel industry will undergo an evolution in emission reduction pathways: process transformation from long-process to short-process steelmaking; low-carbon transition driving non-blast furnace ironmaking development and carbon constraints driving furnace charge structure upgrades. These pathways will collectively reshape the demand structure of iron ore, manifested as strengthened preference for high-grade, low-impurity iron ore concentrates and premium mainstream ore types, while demand for traditional sintering fines tends to narrow. ◼ 1. Process restructuring: the shift from long-process to short-process steelmaking will drive increased demand for mainstream varieties and high-grade ore Under the global backdrop of "carbon neutrality" goals, the steel industry is regarded as one of the key areas for industrial emission reduction. The traditional long process (blast furnace-converter process), due to its reliance on coke and iron ore, is considered a major source of high carbon emissions and has become a key target for regulation and transformation. Many countries have begun shifting toward the more environmentally friendly short process (steel scrap-electric furnace process), but this transition has been relatively slow in China. On one hand, electric furnace steelmaking is largely limited to rebar production; on the other hand, steel scrap supply is constrained. Additionally, considering factors such as melting costs and losses in steel scrap smelting, pig iron costs should be higher than steel scrap prices by 100-150 yuan/mt for steel scrap to be more cost-effective; if the price spread is below this level, pig iron offers better value. In 2025, the price spread between hot metal costs and steel scrap fluctuated in a range of -100-210. Pig iron costs were mostly more favorable than steel scrap, so the share of blast furnace steelmaking in China stayed high. Source: SMM In China, apart from profitability, short-process electric furnaces are also constrained by high electricity prices, steel scrap price fluctuations, and cost disadvantages , resulting in slow capacity growth. Although the national carbon market is already operational, current carbon prices have not been effectively incorporated into trading, which is not enough to drive a large-scale shift from long-process to electric furnaces, and enterprises mostly adopt gradual adjustments . Source: SMM Based on current policy and market conditions, before China's steel industry is formally included in the national carbon market trading and during the early stage of the EU's CBAM policy implementation, the blast furnace-converter long process will remain the dominant mode of global steel production over the next five years. However, under the dual pressures of domestic steel capacity capping and rising carbon prices in the future, China's electric furnace short process is entering a historic development opportunity, with its share of steelmaking set to gradually increase. By 2030, the share of electric furnace steelmaking is expected to reach around 35%. In the long term, this trend will gradually suppress iron ore demand, causing it to weaken. Against the backdrop of oversupply, competition among iron ore varieties will intensify, and therefore high cost-effective varieties with low silicon and aluminum content will become the optimal choice for steel mills. Undoubtedly, mainstream medium and high-grade ore such as PB fines, Mac fines, Newman fines, IOCJ fines, BRBF, and Simandou fines all belong to relatively high-quality varieties. ◼ 2 Low-carbon transition driving non-blast furnace ironmaking development, demand for high-grade iron ore concentrates with Fe content above 65% expected to continue rising Currently, global DRI production accounts for only 10% of total global production. As low-carbon technologies such as hydrogen-based DRI accelerate in application, DRI production share is expected to rise to 13% by 2030. In comparison, China's non-blast furnace ironmaking share is even smaller, with mass production not yet achieved and only leading steel enterprises in the trial production stage. Under current carbon neutrality requirements, China's non-blast furnace ironmaking is facing significant development opportunities. According to incomplete statistics, announced non-blast furnace ironmaking capacity totaled approximately 18 million mt, of which only 2 million mt were under construction, with the remaining 16 million mt of projects still in early stages, carrying relatively high risk coefficients. Whether these projects materialize depends on multiple factors including funding, market conditions, decarbonization policies, and government support, resulting in significant uncertainty regarding future commissioning time. Future projects will primarily be gas-based; current major DRI equipment uses coke oven gas (COG), but in the medium and long-term will gradually shift to green hydrogen. Data source: World Steel Association Data source: SMM Currently, the core requirements for DRI raw materials are "high grade, low impurities," with Fe grade ≥66% and SiO2+Al2O3 ≤3.5%. China's concentrates generally have relatively high silicon content, with some exceeding 10%. Therefore, only a few low-silicon concentrates can be used to produce direct reduced pellet feed. Ex-China high-grade concentrates offer a wider range of options. Data source: SMM As DRI production grows, demand for high-quality iron units is also increasing, leading to a structural rise in the share of high-grade iron ore and pure iron raw materials. As shown in the chart, varieties within the red box all have Fe content above 66%, with Si+Al content around 3.5%; these include some high-grade iron ore concentrates from China, Brazilian pellet feed concentrates, Peruvian concentrates, and emerging Simandou fines, all of which can serve as DRI raw materials. Data source: SMM ◼ 3. Carbon constraints drive furnace charge structure upgrades, with pellet replacing sinter becoming key to carbon reduction, and pellet-making concentrates with grades above 62% set to see significant growth. As China's steel industry pursues structural adjustment, optimization, and green, low-carbon, high-quality development, pellet ore as a premium raw material for blast furnaces has been increasingly favoured by the industry, driving the rapid development of the pellet sector. The energy consumption of the pellet production process is approximately 50% of that of the sinter production process. According to CISA's 2025 statistics, the average energy consumption of the sintering process among its member units was 48.5 kg/mt, while the average energy consumption of the pellet process was 25.23 kg/mt, indicating lower energy consumption in pellet production. Due to the different heat supply methods in pellet roasting compared to sintering, SO2, NOX, and CO2 emissions after combustion are much lower than those from the sintering process. In addition, pellet ore generates much less dust than sinter, making the pellet process more environmentally friendly. The emission comparison between the sintering process and the pellet process is shown in the chart below: Data source: SMM ◼ A high proportion of pellet ore in furnace charge is the direction and demand of current blast furnace charge structure development Compared with other countries in the world, China's blast furnace charge structure is dominated by sinter with a low pellet ratio , while blast furnaces in North America and Europe primarily use high proportions of pellets, with some blast furnaces reaching 100%. For example: SSAB's blast furnace in Sweden had a pellet ratio of 97.2%, Dofasco in Canada achieved 100% all-pellet smelting, and USS No. 14 blast furnace had a pellet ratio of 80%, etc. According to CISA's 2025 statistics, the average fuel ratio per unit of ironmaking at China's key steel enterprises was 523-525 kg/mt, approximately 70 kg higher than the average fuel ratio of European and American blast furnaces. The reason is that China's blast furnace charge is dominated by sinter, with sinter iron grade at around 54-57%, while pellet ore iron grade is above 62%. High sinter usage leads to high slag volume and high energy consumption in blast furnaces. Therefore, against the backdrop of carbon reduction, increasing the proportion of pellet ore usage is imperative. Data source: SMM ◼ Currently, there are three main types of pellet production equipment in China: shaft furnaces, chain grate-rotary kilns, and travelling grates . In recent years, pellet equipment with a single-unit capacity below 1.2 million mt/year (excluding ferroalloy and foundry pig iron pellets) has been classified as a restricted category; therefore, capacity replacement of pellet equipment continues, with new pellet projects predominantly using travelling grates, with single production line capacity mostly at 5 million mt. As a result, current pellet production is mainly based on rotary kilns and travelling grates. These two types of equipment have less stringent raw material requirements compared to shaft furnaces, allowing the blending of multiple ore types such as magnetite, hematite, and limonite. However, it must be concentrate, with a particle size requirement generally of -200 mesh, 70% or above. Commonly used varieties include: domestic concentrate, Ukrainian concentrate, Brazilian concentrate, Middle Eastern concentrate, Chilean concentrate, Australian concentrate, Sierra Leonean concentrate, etc. As the proportion of pellet usage increases in the future, demand for concentrate with grades of 62% and above will continue to expand. ◼ Overall, before 2030, as carbon neutrality policies and Europe's CBAM are still in the early stages of implementation, carbon emission costs have not yet become significantly prominent. Meanwhile, China's steel production is trending downward, while iron ore supply is accelerating, steel mill profits are under pressure, and cost reduction and efficiency improvement remain the industry's mainstream strategy. Therefore, procurement will continue to focus on low- and medium-grade iron ore, demand for non-mainstream ore varieties will remain robust, the price spread among high-, medium-, and low-grade ore will be difficult to widen, and premiums for lump ore and pellets will also stay at current low levels. ◼ After 2030, market requirements for green steel will gradually increase, the share of electric furnace steelmaking and non-blast furnace steelmaking will rise, and overall iron ore demand will decline notably. Although blast furnace capacity will decrease, operating rates may improve, driving down sinter demand while pellet demand increases significantly. This shift will lead to a sharp decline in fines demand and an expansion of market share for mainstream medium-grade ore; meanwhile, demand for high-quality concentrate will rise, pushing the price difference between high and medium-grade ore wider, and pellet premiums will also continue to climb. Additionally, although lump ore demand has some growth potential, the increase will be limited under carbon emission constraints, and lump ore premium elasticity will diminish accordingly.

Over the past half-century of industrialisation, the global seaborne iron ore market took shape and solidified into a "duopoly" supply structure dominated by Australia's Pilbara region and Brazil's Carajás and Iron Quadrangle regions. However, with the evolution of macroeconomic cycles, the structural shift in China's economic growth momentum, and the historic imperative for the global steel industry to transition toward low-carbonisation and green development, this traditional supply landscape is undergoing an unprecedented reshaping. On November 26, 2025, as the first commercial vessel loaded with Simandou iron ore slowly departed Mabariya Port for the open sea, Guinea's Simandou iron mine officially commenced production. As the world's largest and highest-quality greenfield iron ore project, this milestone signalled the gradual rise of the African continent—long relegated to a secondary position—as an important emerging force in the global ferrous metals market. Why should we pay attention to the African market? The African continent's iron ore resources are regarded as the third most important region for global iron ore supply, after Brazil's Carajás region and Australia's Pilbara region. The sheer scale and high grade of its resources account for 13.8% of global iron ore resources. It is also set to be the primary supply-side growth driver over the next five years. Therefore, changes in African iron ore will long remain a key market determining international iron ore prices . This article provides a comprehensive analysis of the current status and landscape of African iron ore and select steel markets, offers an in-depth discussion of future development trends, and presents a data-driven outlook on market changes. I. Global Iron Ore Background According to SMM survey data, as of 2025, global iron ore production is estimated at approximately 2.472 billion mt. Of this, Africa contributed approximately 95 million mt, accounting for nearly 4% of total global production. With the successive commissioning of various large-scale mining projects, Africa's iron ore capacity is expected to double by 2030, reaching a scale of nearly 259 million mt. Assuming no production cuts in other regions, Africa-produced iron ore's global market share is expected to rise to nearly 10%, while the global iron ore market's oversupply is estimated to increase to approximately 220 million mt. (Chart-1: Balance Sheet) Although the international iron ore market has already entered a prolonged cycle of loose supply, the substantive supply shock from African iron ore is expected to materialise gradually only over the next five years. In the short term, based on an estimated 15 million mt of new African shipments in 2026, their outstanding high-grade characteristics are expected to quickly meet steel mills' current demand for low-carbon ore blending, allowing the market to absorb them smoothly, with a relatively mild impact on absolute international iron ore prices. The key point to watch will be from 2028 to 2029. As railway, port, and other infrastructure facilities still under development in Africa are fully connected, the surge in high-grade iron ore production will exert heavy downward pressure on the right side of the global iron ore cost curve. This will not only systematically push down the price center of iron ore but also trigger intense structural squeeze; that is, the survival space for low-grade, high-cost mines will be significantly compressed. This price downcycle is expected to persist through 2028. When international ore prices fall below the marginal cost support level of $90/mt, non-mainstream small mines on the far right of the cost curve will be forced to shut down and exit the market. By then, the global iron ore supply landscape will have completed a new round of reshuffle, re-forming a multi-oligopoly ecosystem dominated by ultra-large, low-cost mines (including new African mines), supplemented by quality mid-sized mines. (Chart-2: Price Forecast Curve) II. African Market Current Landscape: South Africa as the Dominant Leader with Multiple Strong Players, West African Countries Actively Expanding Having analyzed the foundation of the global iron ore market landscape, the focus will now shift to the overall situation in Africa. As the primary driving force behind supply growth over the next five years, Africa's iron ore production is concentrated in West Africa and South Africa. Currently, Africa is dominated by three major countries. Among them, South Africa is the largest producer, with production reaching approximately 67 million mt in 2025, and its export shipments firmly hold an absolute dominant position of approximately 65% of Africa's total iron ore exports. However, constrained by potential structural limitations, the future organic growth potential of South Africa's iron ore industry is relatively limited. As major iron ore projects in other emerging resource-rich African countries successively come into production and release capacity, South Africa's share in Africa's overall export market is expected to face sustained contraction. Next is Mauritania, as Africa's second-largest iron ore producer, with production of 15 million mt in 2025 and export volumes of approximately 12 million mt, accounting for 12% of the African market. Mauritania borders the Atlantic Ocean, possesses abundant high-grade iron ore deposits deep in the Sahara Desert, and enjoys exceptionally favorable geographic location and mineral resources. Moreover, it is within close proximity to European and Middle Eastern markets that urgently need green industrial raw materials, providing it with unique advantages for absorbing the global transfer of green metallurgical capacity. It will be a highly promising iron ore supplier in the future. In addition, Sierra Leone, as another important supply hub in the region, also has an expected production of 12 million mt in 2025, holding a stable share of approximately 12% in the African export market. Chinese-invested iron ore mines within the country are actively expanding their operations. Macro trade flow perspective, based on full-year 2024 trade data, the proportion of African iron ore shipped to the Chinese market was relatively low compared to traditional mainstream mining regions, accounting for only about 60%, while the broader Asian market encompassing China, Japan, and South Korea collectively absorbed approximately 70% of African iron ore shipments. Meanwhile, Western European countries represented by the Netherlands and Germany constituted the core secondary shipping destination for African iron ore, with a trade flow share of nearly 14%. The remaining marginal trade flows exhibited a diversified pattern, radiating broadly to emerging steel capacity clusters in the Middle East, including Bahrain, Oman, and Saudi Arabia. (Chart-3: African Iron Ore Market Overview) Enterprise level, Kumba Iron Ore and Assmang , both based in South Africa, became Africa's largest and second-largest iron ore producers with annual production of 37 million mt and 17 million mt, respectively. Kumba's mines such as Sishen are globally renowned for producing high-grade fines (>62%) and premium lump with excellent physical and metallurgical properties (Premium Lump, Fe 65.2%). Under the current trend of blast furnace emission reduction, this type of lump ore that can be directly charged into furnaces and reduce sintering carbon emissions has been highly sought after by the market, commanding a significant premium. Assmang also possesses high-quality iron ore assets, jointly controlled by African Rainbow Minerals (ARM) and Assore at a 50:50 ratio. Its Assmang fines and Assmang lump (grade at 64-65%) are also high-quality direct furnace charge materials. However, for this enterprise, the biggest bottleneck lies not at the pit head but on the rails. Heavy reliance on Transnet's rail shipping capacity means that logistics bottlenecks frequently cap its shipment volumes. SNIM (Société Nationale Industrielle et Minière de Mauritanie) is Mauritania's state-owned mining company and Africa's third-largest iron ore producer after the two South African companies. Unlike mainstream Australian and Brazilian ore, SNIM's products occupy a unique niche in terms of physicochemical specifications and market segmentation. Its most widely traded product is TZFC fines, characterized by extremely low aluminum (Al2O3) and phosphorus (P) content. As an excellent blending raw material, major steel mills prefer to blend SNIM ore fines with high-aluminum Australian fines (such as certain Pilbara blend ores) to significantly dilute the impurity ratio in furnace charge and optimize blast furnace performance. (Chart-4: Top-Tier Enterprises) III. Transformation of the African Market: Major Producing Countries May Stagnate While Emerging Projects Become Key Growth Drivers So where will future growth come from? According to SMM observations, the African market is expected to undergo significant structural changes over the next five years. Multiple large-scale iron ore projects across African countries are already under construction and plan to commence production before 2030. Based on estimates, Africa's iron ore supply is expected to grow substantially from approximately 95 million mt currently to 260 million mt over the next five years, representing a cumulative increase of up to 85%. The market landscape will also shift from South Africa-dominated exports led by Western players to Guinea-dominated exports. (Chart-5: African Market Production Trend) The primary growth driver will come from Guinea in West Africa. The country's renowned Simandou iron ore mine, jointly developed by multiple enterprises, is currently the world's largest undeveloped high-grade open-pit hematite deposit. With resource reserves exceeding 5 billion mt and a designed capacity of 120 million mt, it is the project with the greatest strategic potential to reshape the existing iron ore market landscape. Since the first ore shipment in late November 2025, as of Q1 2026, Simandou's main export port, Morebaya Port, has cumulatively shipped nearly 1.6 million mt. Blocks 1 and 2, developed under the leadership of the Winning Consortium Simandou (WCS), have been successfully commissioned, with 2026 capacity expected to be achieved and shipments expected to reach full production of 60 million mt within the next 2–3 years. Blocks 3 and 4, which are expected to commence production in Q1 2026, are led by Simfer (a Rio Tinto & Baowu joint venture) and are expected to ship 5 million mt of ore in 2026, reaching full production of 60 million mt over 30 months. In other words, Guinea is expected to reach 120 million mt before 2030, vaulting to become the world's second-largest iron ore project, behind only Brazil's S11D project (with a post-expansion designed capacity of 200 million mt, expected to commence production in 2030). Other countries such as Liberia, Gabon, Sierra Leone, and Congo Republic all have iron ore projects under development, with a combined capacity of approximately 46 million mt planned to commence production by 2030. The largest among these is the Tokadeh Phase II project (Tokadeh Phase II) in Liberia, owned by ArcelorMittal (AML), which is expected to commence production in H2 2026 and reach full production of 20 million mt capacity by year-end, with iron ore concentrate expected to exceed Fe 66%. Given that AML's steelmaking capacity in Europe cannot absorb such a massive increase in the short term, the majority of Tokadeh 's products are expected to flow into the international market for trading, exerting downward pressure on iron ore concentrate prices. Currently, the largest exporting country, South Africa, is expected to largely maintain its production within the range of 63–67 million mt, with a risk of slight decline. The primary reason is that South Africa's iron ore transportation is highly dependent on the heavy-haul railway line (TFR) from Sishen to Saldanha Port. In recent years, Transnet Freight Rail (TFR), under South Africa's national transport company Transnet, has seen a significant decline in transport capacity due to numerous issues including locomotive and rolling stock shortages, frequent cable theft, and prolonged underinvestment in infrastructure, resulting in severely reduced transportation capacity for major bulk commodities such as iron ore and coal. South Africa's largest iron ore mine, Kumba, in its 2025 year-end financial report released in February 2026, indicated that its total finished product inventories reached as high as 7.5 million mt , increasing rather than decreasing compared to 6.9 million mt at the end of 2024. As railway transport capacity failed to match mine production capabilities, major South African iron ore producers were forced to accumulate large inventories at mine sites. To prevent inventory overflow, miners had to proactively lower production guidance. Although miners have been working to address transportation issues, the deep-rooted railway problems are difficult to resolve in the short term. Beyond 2030, there is also Mauritania's SNIM strategic growth blueprint. In the first phase (Horizon 1), the company plans to raise annual capacity to 45 million mt by 2031 through implementing lean production, equipment and technology upgrades, and joint development of new reserves. Of this, 20 million mt will be absorbed by SNIM's own wholly-owned capacity, while another 25 million mt will be achieved through attracting international capital to form joint ventures. Furthermore, SNIM has even set its sights on 2045 (Horizon 3), formulating a long-term goal of raising annual capacity to 80 million mt . In addition, there is the MIFOR project in the DRC. On March 26, 2026, the DRC signed a relevant memorandum of understanding with China, and the MIFOR project was listed as a flagship project with priority support. The mine is estimated to hold cumulative resources of 15 billion to 20 billion mt, with an average grade exceeding 60%. Its potential scale is considered to be approximately 2.5 times that of the Simandou project in Guinea. The first phase of the project is expected to cost $28.9 billion, involving the construction of a heavy-haul freight railway combined with Congo River shipping, ultimately connecting to the Banana deep-water port on the Atlantic coast. Initial annual production is expected to be 50 million mt, with a long-term goal of expanding to 300 million mt per year . All these projects are destined to make Africa an indispensable source of iron ore supply in the future. (Chart-6: Selected African Iron Ore Projects) IV. Global Steel Industry Chain Transformation: Will Africa, as a Hub of High-Grade Ore, Empower DRI Production? Notably, most of Africa's currently operating and planned iron ore projects have an average total iron grade (Fe) largely above 65% , with extremely low impurity content. This scarce high-grade ore is an ideal raw material for the direct reduced iron (DRI) process. As the DRI-EAF green steel route gains traction in Europe, the US, and China, future demand for iron ore with grades of 65% and above will surge exponentially. This will confer an exceptionally high "grade premium" on major iron ore projects including South Africa's Kumba, Guinea's Simandou, and other mines coming into production in the future. In the long run, the pricing benchmark for iron ore is inevitably shifting away from the traditional Platts 62% index, and African miners will gain bargaining leverage when renewing long-term agreements, thereby reshaping the global industry chain profit distribution landscape. In line with the global carbon neutrality trend, international investors, encouraged by local governments, are actively deploying high-value-added processing facilities, including DRI plants and high-grade pellet plants, aiming to fully leverage Africa's abundant high-grade iron ore resources and enormous energy potential for DRI production. Based on SMM's observations, approximately 200,000kt of DRI capacity is expected to emerge in Africa by 2030. The largest project among them is an 8.1 million mt DRI complex located in Libya, a joint venture between Turkish steel mill Tosyali and Libya's national steel company. (Chart-7: African DRI Projects) As China advances its "dual carbon" goals, the steelmaking industry is undergoing corresponding adjustments. China has set out a strategic blueprint for carbon peaking by 2030 and carbon neutrality by 2060. The traditional high-carbon-emission long-process steelmaking route dominated by blast furnace-converter operations is facing extremely stringent capacity replacement policies and environmental protection regulations. Meanwhile, the global trade system is also accelerating the imposition of carbon costs — for example, the implementation of the EU's Carbon Border Adjustment Mechanism (CBAM) — compelling the global steel supply chain to accelerate its transition from the source toward a low-carbon or even zero-carbon "green steel" era. Under this irreversible transformation trend, the short-process route combining DRI with electric furnace (EAF) has become the most commercially feasible decarbonization pathway. To meet the surging global demand for green steel in the future, market forecasts indicate that by the 2030s, global DRI designed capacity will need to increase by hundreds of millions of metric tons. This dramatic expansion in production scale will profoundly reshape the global steel supply landscape. The share of traditional pig iron production will gradually decline, while low-carbon DRI supply will directly determine the competitiveness of major economies in the global green steel market. In particular, the "hydrogen metallurgy" technology, which uses green hydrogen to replace natural gas and coal for iron ore reduction, is widely recognized by the industry as the core to achieving ultimate zero-carbon steelmaking. (Chart-8: Reshaping of the Steel Industry Chain Under Green Transformation) Represented by world-class high-quality iron ore projects such as Simandou in Guinea, the gradual commissioning of these super mines is expected to inject over 100 million mt of high-grade iron ore supply into the global market annually, significantly alleviating the global shortage of DRI-grade ore. More critically, North Africa and West Africa possess solar and wind energy potential that is second to none globally, enabling large-scale green hydrogen production at extremely low costs locally. This perfect combination of "high-grade ore + affordable green hydrogen" has led multinational capital and steel giants to increasingly favor establishing DRI production lines directly on African soil, reducing iron ore locally into low-carbon Hot Briquetted Iron (HBI) that is convenient for transport, before shipping it to electric furnaces in Asia and Europe for smelting. As a result, Africa will formally transition from the old era to become an indispensable part of the green iron production chain.

On 26 March 2026, the Democratic Republic of the Congo and China signed a Memorandum of Understanding that designates the Grande Orientale Iron Ore Project (MIFOR) as a flagship venture receiving priority support from Chinese stakeholders. It is estimated that this mining concession holds cumulative resources of between 15 billion and 20 billion tonnes, boasting an average iron grade exceeding 60 per cent. The first phase of the development is projected to require a capital expenditure of 28.9 billion US dollars. Initial production is targeted at 50 million tonnes per annum, with a long-term strategic objective to expand operational capacity to 300 million tonnes per annum.

I. Supply-Demand Pattern Shift Puts Iron Ore Prices on a Downtrend In 2021, driven by inflation expectations from global quantitative easing, frequent supply-side disruptions in Brazil and Australia, resilient demand in China, and strong speculative sentiment, iron ore prices hit a record high of $219.77/mt in July that year, with Platts’ annual average price as high as $160/mt ; they then entered a prolonged downtrend. In 2025, the annual average iron ore price was $102, down about 36% from the 2021 average. Source: SMM Iron ore prices have continued to fall in recent years, mainly due to the global project investment boom spurred by high prices before 2021. After 2024, multiple large iron ore projects worldwide entered a concentrated commissioning phase, and the market’s supply-demand pattern shifted from tight to loose, with the supply-demand gap widening from -12 million mt to 46 million mt. Meanwhile, China has implemented crude steel production cuts since 2022, significantly curbing iron ore demand. Coupled with persistent weakness in real estate, an overall downturn in the steel industry, and an overseas economic slowdown, among other factors, iron ore demand declined markedly. Entering 2025, a rebound in China’s steel exports drove iron ore demand to increase slightly, while capacity in emerging steel-producing countries such as Southeast Asia was gradually released, narrowing the supply-demand gap somewhat. Over the long term, however, iron ore supply is still on a growth trend, market expectations remain bearish, and prices are pressured to set new lows repeatedly. Source: SMM (the forecast assumes an extreme balance under normal commissioning of new mines and no voluntary production cuts by mines) II. Mine Costs Form a Solid Bottom Support for Iron Ore Prices From the global iron ore cost curve, about 90% of global mine cash cost is no higher than $85/mt, and about 93.8% is no higher than $90/mt. International mining giants represented by FMG, BHP, Rio Tinto, and Vale have costs far below those in China and other non-mainstream countries, forming the main body on the left side of the cost curve in the chart—low and relatively flat—which explains their strong cost competitiveness and earnings resilience in the global market. At present, the $85-90 cost line is the lifeline for the vast majority of mines; once prices remain below this range for an extended period, high-cost capacity will be forced to exit, thereby supporting prices. China’s iron ore mines due to low raw ore grade and high underground mining costs, among other reasons, currently have a nationwide per-mt processing cost of about 595 yuan/mt, equivalent to around $85 . Its costs have long been at the high end globally, serving as the "anchor point" and "ceiling" of the cost curve. The high cost and low production of China's domestic iron ore mines have led the steel industry to heavily rely on imports for raw materials, and fluctuations in international ore prices directly impact the profit stability of the domestic steel industry. Therefore, promoting domestic resource supply, investing in low-cost overseas resources, and developing steel scrap recycling are crucial for the strategic security of China's steel industry. Data source: SMM III. The global iron ore supply has long been characterized by a landscape dominated by the "Big Four" mines, supplemented by "non-mainstream" mines. Currently, the iron ore production industry is highly concentrated, primarily following a pattern dominated by the "Big Four" mines, supplemented by "non-mainstream" mines. Australia and Brazil have long contributed over half of the global iron ore production. Australia, leveraging advantages such as high resource concentration, low mining costs, and stable supply, firmly holds its position as the world's largest producer and exporter; while Brazil is renowned for its high-grade ore and is the world's second-largest iron ore exporter. Data source: SMM The "Big Four" mines, consisting of Rio Tinto, BHP, FMG, and Vale, have long dominated global iron ore supply, accounting for approximately 70% of global production. Data source: SMM The Rise of Emerging Mines Promoting the Multipolar Development of Global Iron Ore In recent years, India has actively promoted domestic mining development, leading to a significant increase in production; since 2023, its iron ore production has surpassed that of China, and it shows a continuous expansion trend, maintaining an annual growth rate of 7%, gradually becoming a new force in regional supply growth. Emerging enterprises such as India's National Mineral Development Corporation (NMDC) and South Africa's Anglo American are gradually expanding capacity, enhancing their influence in the international market. Meanwhile, countries such as Russia, Kazakhstan, Iran, and regions in Africa are also actively developing domestic iron ore resources, seeking to increase their voice in regional markets, driving the global iron ore supply landscape from high concentration towards gradual multipolar development. Data source: SMM IV. Australia Firmly Holds the Top Spot, India Becomes a New Growth Engine From the perspective of major producing countries, Australia still firmly ranks first globally, with iron ore production of approximately 900 million mt in 2025, accounting for one-third of the global total, and maintaining a stable annual growth rate of about 2%. Brazil ranks second; after the 2019 dam collapse, production once fell sharply. Although it has recovered somewhat over the past two years, the increase has been relatively limited. China’s production scale is relatively large, but due to frequent safety incidents and the continued impact of the environmental protection-driven production restriction policy, production has not increased but instead declined in recent years. By contrast, India, as an emerging producer, has seen production rise steadily over the past decade, and is expected to post an increase of about 7% by 2030. Source: SMM V Over the next three years, the world will usher in a new peak in mine commissioning In addition to supply from existing mines, there are currently multiple large-scale iron ore projects under construction worldwide, with the number of mines expected to be commissioned in 2026 at six, mainly located in Africa and Brazil. Representative projects include Vale’s northern expansion “S11D +20mtpa,” the northern block of Guinea’s Simandou iron ore project, and the Nimba iron ore project. 2026 will be the year with the most concentrated new supply over the next three years. With the northern block of Simandou officially commencing production, the overall capacity ceiling of the mining area will, with capacity ramp-up, rise to 120 million mt, becoming the core incremental source of global iron ore supply over the next five years. From 2027 to 2028, projects expected to commence production will mainly come from China, including the Xi’an Mountain iron ore mine and the Honggenan iron ore mine, adding about 25 million mt of iron ore supply to the domestic market. Overall, as emerging producers continue to release capacity, and traditional suppliers such as Australia and Brazil consolidate their export advantages through expansion projects, the global iron ore supply structure will become more diversified. A new cycle of capacity release has gradually begun, and the loose supply landscape is expected to continue deepening over the next several years. Source: SMM Simandou Project Commissioning Reshaping the Global Iron Ore Supply Landscape Among the many new projects, Africa’s Simandou iron ore is particularly noteworthy. The mine is expected to reach annual capacity of 120 million mt, and the ore’s average grade exceeds 65%, providing the market with a high-grade, high-quality option beyond Australia and Brazil, and becoming an important variable in the recent contest over the global iron ore supply landscape. In terms of project progress, the Simandou iron ore project has entered a substantive shipment phase; as logistics corridors are gradually opened up, the mining area’s substantive impact on global supply will gradually become evident. Source: SMM Nearly 400 million mt of Capacity Release by 2030, Global Iron Ore Market Faces Impact With the entry of emerging producers, iron ore supply is beginning to diversify. Projects led by Simandou iron ore are breaking the industry landscape and taking the iron ore market into a new stage. Looking ahead to the next five years, global iron ore capacity is expected to see a wave of concentrated releases, with incremental supply mainly coming from two major regions: Africa and Australia . Leveraging the development of new high-grade mines such as Simandou, Africa is reshaping the global supply landscape; meanwhile, Australia, relying on its existing capacity base and ongoing expansion projects, is further consolidating its export-dominant position. Overall, the global iron ore supply landscape is evolving toward greater diversification and a looser market. Source: SMM VI Simandou High-Quality Iron Ore Enters the Market; Global Iron Ore Enters an Era of “Quality Upgrading” As some older mines gradually enter a period of resource depletion , coupled with the fact that many newly commissioned projects are dominated by mid- to low-grade ore, the average global iron ore grade shows a downward trend from 2025 to 2026 . However, as high-grade mines such as Simandou are commissioned one after another, the share of high-grade ore supply is expected to increase, and is projected to drive a rebound in the overall global iron ore grade in 2027. Source: SMM VII “Green Steel” Reshapes the Global Crude Steel Production Landscape From a policy perspective, the low-carbon transition represented by “green steel” is profoundly reshaping the global crude steel production landscape . Whether in China or Europe, carbon neutrality has become the core theme for the future development of the steel industry. Therefore, whether it is China’s ongoing capacity replacement policy or the EU’s Carbon Border Adjustment Mechanism (CBAM) that is about to be fully implemented , both clearly indicate that the global steel industry is accelerating its transition toward low-carbon and green development. Achieving carbon neutrality across the entire industry chain is no longer an isolated task for a single link, but must rely on close upstream-downstream coordination and deep integration of technological pathways. Source: SMM Technology Reshaping: Green Iron Supply + Green Production Demand Against the broader backdrop of carbon neutrality, merely maintaining the current supply-demand structure dominated by iron ore can no longer meet future low-carbon requirements. The deeper need of industry transformation lies in reconstructing metallurgical processes: resource-rich countries—such as Australia and Brazil, traditional major iron ore exporters—need to fully leverage their renewable energy endowments and mineral advantages, shifting from simply exporting iron ore to producing high-grade, low-carbon-footprint direct reduced iron (DRI) or hot briquetted iron (HBI) and other high value-added intermediate products. By shipping this clean-energy-driven “green DRI” to steel consumption hubs and integrating it with local green electric arc furnace (EAF) processes, it can effectively replace the traditional “blast furnace–converter” long process, thereby substantially reducing carbon emissions at the source. This multinational collaborative model of “high-quality resources + green energy + short-process” is not only a critical measure to address trade barriers such as the Carbon Border Adjustment Mechanism, but also an essential pathway to build a new global green steel supply chain and drive deep decarbonization across the industry. Data source: SMM Rising Share of Electric-Furnace Steelmaking, Stronger Substitutability of Steel Scrap, Squeezing Iron Ore Demand Driven by carbon-neutrality targets, the steel industry, as a major source of carbon emissions in the industrial sector, has drawn close attention for its emissions-reduction pathway. Among these, the traditional long-process route centered on “blast furnace–converter,” due to its heavy reliance on coke and iron ore, is regarded as a primary source of carbon emissions and has therefore become a key focus of regulation and retrofitting in various countries. By contrast, the short-process route represented by “steel scrap–electric furnace,” with a significantly lower carbon-emissions intensity, is being favoured by an increasing number of countries. This structural shift has driven the share of electric-furnace steelmaking in global crude steel production to continue rising. Data source: SMM From an economic perspective, the substitution relationship between steel scrap and pig iron is typically measured by the price spread. Generally, after factoring in steelmaking costs and losses, pig iron costs should be about 100-150 yuan/mt higher than steel scrap prices ; this range is viewed as the cost-performance equilibrium band: if steel scrap prices are lower than pig iron costs by more than this threshold, steel scrap is more economical; otherwise, pig iron has a more pronounced advantage. In 2025, the average price spread between pig iron and steel scrap was 122 yuan/mt, lower than the 2024 average of 211.8 yuan/mt, and also largely within the cost-performance equilibrium band. By contrast, the 2024 spread was significantly above the upper limit of the equilibrium band, indicating that steel scrap offered a more prominent cost-performance advantage at that time. After the spread narrowed in 2025, the economic advantage of steel scrap weakened somewhat. As a result, in the short term, there is limited room for China to increase the share of electric-furnace steelmaking; overall, it remains at a relatively low level and still lags far behind the global average. This also reflects that, at the current stage, cost factors still impose a substantive constraint on the choice of smelting process routes. Data source: SMM Taken together, the blast furnace–converter long-process route will remain the dominant model for global steel production over the next five years, but the shares of electric furnaces and steel scrap usage will increase year by year; in the long run, this trend will suppress iron ore demand, causing it to weaken gradually. Data source: SMM VIII Global Total Iron Ore Demand in 2030 to Be About 2.4 Billion mt, with Gradual Shifts in Global Flows As China began encouraging domestic steel mills to develop overseas markets while adjusting the domestic industry chain’s transformation toward producing high value-added products needed by the manufacturing sector, global crude steel production began to rebound gradually. Data Source: SMM From the perspective of the global demand structure, although crude steel production outside China is entering a new round of development, with capacity expansion particularly notable in regions such as India and Southeast Asia, a considerable portion of the incremental increase comes from electric furnace processes, providing limited substantive boost to iron ore demand. Meanwhile, as the world’s largest iron ore consumer, China’s crude steel production has entered a downward trajectory, constituting the primary source of demand-side reductions. Overall, overseas increments are unlikely to fully offset China’s reductions. It is expected that by 2030, total global iron ore demand will be approximately 2.4 billion mt, with overall growth trending toward a slowdown. Compared with the mild growth on the demand side, the supply side remains in a phase of continuous expansion. The oversupply landscape will become an important factor that suppresses ore prices over the long term. Data Source: SMM SMM will continue to track the impact of changes in iron ore supply and demand on prices. Comments are welcome—scan the code to follow us! Data Source Statement: Except for publicly available information, all other data are processed and derived by SMM based on publicly available information, market communication, and SMM’s internal database models, for reference only and not constituting decision-making advice. Scan the code to access information for free

SMM Alumina Morning Comment 2.2 Futures: Last Friday's night session, the most-traded alumina futures contract AO2605 opened at 2,767 yuan/mt, reached a high of 2,836 yuan/mt, hit a low of 2,748 yuan/mt, and closed at 2,818 yuan/mt, up 50 yuan/mt from the previous day. Open interest decreased by 17,800 lots to 425,000 lots, indicating cautious market trading. From a technical perspective, the closing price was above MA5 (2,789.40), MA10 (2,746.30), and MA30 (2,758.17), providing some upward momentum. Meanwhile, the MACD indicator DIF (2.91) crossed above DEA (-4.6), with the low-level golden cross continuing and the histogram at 15.02. Alumina futures are expected to remain in the doldrums in the short term. Industry Updates: 1) In January 2026, China's metallurgical-grade alumina production decreased 1.78% MoM and 2.6% YoY. As of month-end January, nationwide existing capacity was approximately 110.32 million mt, with operating capacity down 1.78% MoM and 3.56% YoY. 2) On January 30, 2026, Chalco, a publicly listed firm under Chalco Group, issued an announcement regarding the planned acquisition of equity in a Brazilian aluminum company, aimed at enhancing resource security and optimizing industrial layout. The transaction will be conducted through a prudent and market-oriented approach. As a core holding enterprise under Chalco Group, Chalco possesses a complete entire industry chain. It plans to establish a joint venture in Brazil with Rio Tinto International Holdings Limited through its wholly-owned subsidiary Chalco Hong Kong Limited, and through this joint venture, acquire 68.596% equity in Mineração Rio do Norte (MRN) held by Votorantim. Upon completion, MRN will become a controlling subsidiary consolidated into Chalco's financial statements. This transaction introduces Rio Tinto, a partner with extensive international mining experience. Rio Tinto is a global comprehensive mineral resource supplier and one of the world's largest resource extraction and mineral product suppliers. The two parties have maintained a strong cooperative relationship over the years, achieving collaborative results in multiple areas including the Simandou iron ore project. 3) According to market sources, PT Kalimantan Alumina Nusantara (KAN), approximately 80% owned by Press Metal Group, is constructing an alumina refinery with an annual capacity of 1.2 million mt in West Kalimantan, Indonesia. The project is expected to gradually commence production by year-end 2026 or early 2027. 4) The Indonesian government is preparing to establish a new state-owned enterprise named Perminas, set up by the Daya Anagata Nusantara investment management agency, which will be responsible for the operational management of strategic mineral mines. Energy and Mineral Resources Minister Bahlil Lahadalia stated that Perminas will handle strategic commodities such as rare earth metals and other critical minerals, without specifying the types of minerals. When asked whether Perminas would soon take over existing mines, Bahlil said the government would closely monitor subsequent developments. Ore: As of January 30, 2026, the SMM imported bauxite index was at $64.38/mt, down $0.87/mt from the previous trading day. The SMM Guinea FOB average price was at $39/mt, down $1.5/mt from the previous trading day. The SMM Guinea bauxite CIF average price was at $61/mt, down $1.5/mt from the previous trading day. The SMM Australian low-temperature bauxite CIF average price was at $62.5/mt, down $0.5/mt from the previous trading day. The SMM Australian high-temperature bauxite CIF average price was at $57.5/mt, down $0.5/mt from the previous trading day. The Malaysian bauxite CIF average price was at $47/mt, unchanged from the previous trading day; the Malaysian bauxite CIF (washed) average price was at $61/mt, down $0.5/mt from the previous trading day. The Ghanaian bauxite CIF price was at $73.5/mt, unchanged from the previous trading day. The bauxite CFR (Turkey) price was at $71.5/mt, down $2/mt from last Friday. Domestic ore side, bauxite production resumptions in Shanxi were active, with currently ample supply and prices under pressure. Imported ore side, intended transaction prices between buyers and sellers recently declined from earlier levels, with current market transactions sluggish. Some alumina refineries reported that amid falling ore prices, procurement plans remained cautious. SMM will continue to monitor domestic and overseas mines production, port shipments, and price trends. Spot Prices: As of January 30, 2025, the SMM alumina index was at 2,622.71 yuan/mt, down 2.56 yuan/mt MoM. The SMM Shandong alumina index was at 2,550.71 yuan/mt, down 0.27 yuan/mt MoM. The SMM Henan alumina index was at 2,620.79 yuan/mt, down 1.06 yuan/mt MoM. The SMM Shanxi alumina index was at 2,606.74 yuan/mt, down 0.82 yuan/mt MoM. The SMM Guizhou alumina index was at 2,698.06 yuan/mt, down 6.21 yuan/mt MoM. The SMM Guangxi alumina index was at 2,680.59 yuan/mt, down 11.07 yuan/mt MoM. Spot-Futures Price Spread Daily Report: According to SMM data, on January 30, the SMM alumina index was at a discount of 139.29 yuan/mt against the most-traded contract's latest transaction price at 11:30 AM. Warrant Daily Report: On January 30, total registered alumina warrants increased by 9,583 mt from the previous trading day to 171,100 mt. Shandong region alumina warrants remained unchanged at 7,796 mt. Henan region alumina warrants remained unchanged at 0 mt. Guangxi region alumina warrants increased by 2,402 mt to 7,505 mt. Gansu region alumina warrants increased by 6,300 mt to 16,500 mt. Xinjiang region alumina warrants increased by 3,283 mt to 139,300 mt. Markets Outside China: As of January 30, 2026, the FOB Western Australia alumina price was $308/mt, the ocean freight rate was $20.2/mt, and the USD/CNY selling rate was around 6.97. This translated to a domestic mainstream port selling price of approximately 2,663.86 yuan/mt, slightly above the SMM alumina index price by 41.15 yuan/mt. According to SMM model calculations, the import window was closed. Summary: Overall, as of last Thursday, China's alumina market inventory edged up slightly, with the overall oversupply pattern continuing. Currently, some alumina refineries have initiated maintenance, with enterprises across various regions arranging production shutdowns of varying scales, leading to a decline in industry operating rate and a weekly production decrease of 35,000 mt to 1.636 million mt. Inventory side, due to the increase in enterprises undergoing maintenance, alumina in-factory inventory decreased by 3,000 mt to 1.2408 million mt. Aluminum enterprise raw material inventory edged up slightly to 3.603 million mt, mainly driven by continued shipments under long-term contracts. Warrants, attracted by previously strong futures prices, saw increased delivery willingness, rising by 40,000 mt to 159,100 mt, while in-transit and platform inventory decreased by 30,000 mt as cargoes gradually arrived at end-users. Overall, although the pace of inventory buildup has slowed compared to earlier periods, overall industry inventory pressure persists, and the destocking progress has fallen short of expectations. Going forward, attention should be paid to the execution of enterprise maintenance plans. If supply-side contraction does not continue, inventory is expected to maintain a slight accumulation trend next week, and spot alumina prices will remain in the doldrums. [Data other than publicly available information is derived from public information, market communication, and SMM's internal database models, processed by SMM for reference only and does not constitute decision-making advice.]

Australian producer Fortescue applied to Western Australia’s Environmental Protection Authority (EPA) on February 17, 2026, to build the Wyloo North iron ore project in the Pilbara. The project has a planned capacity of 12 million tonnes per annum (MTPA) and an average iron grade of 59.6% Fe. Fortescue plans to process the ore at its existing Eliwana facility to optimize current infrastructure.