【SMM Steel】Volvo Korea and POSCO signed an MoU to develop high-performance materials and manufacturing tech for future construction machinery, focusing on carbon neutrality and electrification. POSCO provides advanced metals and processes; Volvo leads equipment design. A key goal is structural lightweighting via high-strength steel. The innovations will be used in excavators at Volvo's Changwon plant, securing the supply chain from raw materials to final assembly.

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.

[How Should Zinc Consumption Be Viewed Against the Backdrop of Geopolitical Conflicts?] Q1 2026 had passed, and the overall recovery in post-holiday consumption was somewhat delayed. How would consumption perform going forward?

[SMM Steel] On March 31, 2026, the German government approved its Climate Protection Program 2026, allocating €2.9 billion to accelerate industrial electrification and carbon neutrality by 2045. While the German Steel Industry Association (WV Stahl) welcomed the plan’s focus on low-carbon lead markets, it warned of a lack of concrete support for rail infrastructure, which is vital for green logistics. The association also urged the inclusion of "Made in Europe" criteria to protect local industrial competitiveness and ensure public subsidies benefit domestic manufacturing.

On the evening of March 18, 2026, at Chery Automobile Battery Night 2026 in Wuhu, Anhui, Chery unveiled its Rhino all-solid-state battery technology. It had completed the development and pilot production of a 60Ah, 400Wh/kg all-solid-state battery cell and was advancing toward an ultra-high energy density of 600Wh/kg.

The 2026 SMM (3rd) Global Renewable Metal Industry Chain Summit & Battery Recycling Forum will be held in Tokyo, Japan, from May 11–12, 2026. The summit aims to bring together leading global enterprises, research institutions, industry experts, and policymakers in the fields of renewable metals and battery recycling.

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 Steel】From 2026, BMW will use thyssenkrupp's bluemint® recycled steel in the BMW iX3 for outer panels, interior parts, and the battery housing. It replaces iron ore with scrap in blast furnaces, cutting CO₂ while keeping high surface quality and formability. The steel offers fire protection and EM shielding for the battery. No factory changes are needed as properties match conventional steel. The deal supports thyssenkrupp's shift to carbon neutrality, including a planned H₂-ready DRI plant. By 2045, all output aims to be climate-neutral bluemint® steel.

Li-ION BATTERY China 2025 Officially Announced and Scheduled

[SMM Analysis: The Uncommon Yet Not Ordinary Prussian White: How Can Low-Cost Materials Sustain Competitiveness?] SMM News on June 18: Driven by the goal of carbon neutrality, sodium-ion batteries have emerged in the fields of energy storage systems (ESS) and start-stop applications due to their advantages of abundant resources and low cost. The Prussian route, as one of the three major cathode routes for sodium-ion batteries, is gradually gaining attention. Prussian materials are currently divided into two types: Prussian blue and Prussian white. The main reason for the color difference between the two cathodes lies in crystalline water. Prussian white requires further dehydration based on Prussian blue, so precise control of crystalline water is necessary for Prussian white...