Right now the price of gold sits around $5,100 an ounce, which is double where it sat just over one year ago. And the war in Iran could propel the price upwards even further.

Secondary Zinc Oxide Production Fell in February, While Secondary Zinc Oxide Payables Remained Relatively Firm. What Trend Will Secondary Zinc Oxide Show in March?

This week, ferrous metals rebounded from the bottom. At the start of the week, coking coal and coke led the futures higher, mainly driven by rising crude oil prices in the overseas market, which pushed the energy and chemicals sector stronger accordingly; mid-week, both the U.S. and Iran signaled a more relaxed stance toward war, easing geopolitical tensions, while coal prices fell in tandem, weakening the cost-side logic, and ferrous metals fluctuated at highs; in the latter half of the week, worsening short-term liquidity issues in BHP's iron ore port inventory triggered stronger iron ore prices in the overseas market, while the Middle East situation remained volatile, reinforcing cost support and pushing ferrous metals higher again. In the spot market, supported by futures, end-user and arbitrage purchase sentiment both improved WoW this week......

Among precious and rare metals, osmium is a niche yet irreplaceable material, overshadowed by gold, silver, platinum and palladium but critical for high-end industry and scientific research thanks to its unique physical and chemical properties. This report breaks down osmium’s core attributes, supply, applications and market traits to unveil the “densest natural metal”. I. Basic Profile: A Distinct Platinum Group Metal Osmium (Os, atomic number 76) is a Group Ⅷ transition metal and part of the platinum group metals (PGMs), extremely scarce in nature. It has no independent deposits, only extracted and purified via platinum ore smelting alongside platinum, iridium, ruthenium, rhodium and palladium, ruling out large-scale standalone mining. Its standout properties: unmatched density (22.59g/cm³ at 20℃, higher than gold and platinum), exceptional heat resistance (melting point 3033℃, boiling point over 5000℃), and high hardness & corrosion resistance (Mohs hardness 7). It is highly brittle with poor plasticity, mostly used in powder or alloy forms. Key Safety Warning: Osmium oxidizes to toxic, volatile osmium tetroxide (OsO₄) when heated above 100℃ in air. Full-process operations (smelting, storage, transport, processing) require inert gas protection, raising production and application thresholds. II. Supply Landscape: Extreme Scarcity & Monopolized Output Osmium is far rarer than gold and platinum, with a crustal abundance of just 0.001ppm, one of the lowest stable elements globally. Proven recoverable reserves are extremely limited and highly concentrated. Global output hinges entirely on platinum mining and smelting, staying at a tiny scale: annual global production is roughly 1 ton (data from International Platinum Group Metals Association), while China’s annual output is less than 100kg. South Africa and Russia dominate global osmium resources and smelting capacity, forming a highly monopolized, inelastic supply market. Tight supply-demand balance persists, supporting strong price resilience and volatility. III. Core Applications: High-End & Irreplaceable Scenarios Despite low production and narrow application scope, osmium is a rigid material for high-precision sectors with no low-cost substitutes, focusing on four key fields: Special Hard Alloys: Osmium-based alloys excel in hardness, wear and corrosion resistance, used for high-precision bearings (luxury watches, instruments), premium pen nibs, medical scalpels and high-end mechanical wear parts. Industrial Catalysis: Osmium and its compounds act as high-efficiency catalysts for fine chemical and organic synthesis (hydrogenation, oxidation), boosting process efficiency and product purity with stable low-volume demand. Scientific Research: Toxic osmium tetroxide is an irreplaceable stain for electron microscopy samples in materials and life sciences; high-purity osmium powder serves as a specialty lab consumable. Aerospace & Military: Leveraging high density and thermal stability, osmium is used for specialty high-temperature components, precision guidance parts and high-end electrical contacts, with high added value and growing demand amid industrial upgrading. IV. Core Market Traits Osmium is a niche PGM marked by extreme resource scarcity, monopolized inelastic supply, rigid high-end demand and total irreplaceability. Unlike bulk commodities, its market is driven by supply shifts, high-end industrial demand and compliance costs, with a small scale and low trading frequency, remaining a critical material for high-end industry and scientific research.

SMM March 13: This week, China’s domestic tungsten market exhibited high-level oscillations with intensified supply-demand competition. Multiple mines put products up for auction during the week, but transactions were bleak.As of March 13, tungsten prices remained largely stable, yet market sentiment became extremely divided.

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

As of March 10, the operating rate of 50 electric furnace steel mills nationwide mainly producing construction materials was 35.38%, up 24.62% WoW from the previous period; the capacity utilization rate was 29.34%, up 22.46% WoW; daily average production of construction materials was 65,300 mt, up 50,000 mt WoW.

Capacity side, according to incomplete statistics, China’s alkaline electrolyzer market remained at 43.77 GW and the PEM electrolyzer market remained at 2.7 GW, with no new capacity added. No offline delivery information was available this week. Project-related developments: Jiangsu Guofu Hydrogen Energy Technology Equipment Co., Ltd.: Its indirectly wholly owned subsidiary, Xinjiang Guofu Mingzhi Hydrogen Energy Technology Co., Ltd., entered into a sales agreement with independent third party Hefei Zhongke Hecheng Green Energy Co., Ltd. for hydrogen production equipment for a green fuel base demonstration project featuring 20,000 mt of green electricity-based hydrogen production and flexible synthetic ammonia. The total contract value exceeded 55 million yuan. Under the agreement, Guofu Mingzhi will supply the client with six sets of 1,000 Nm³/hour alkaline electrolyzers and auxiliary equipment, such as rectifier transformers, rectifier cabinets, and separation and purification equipment. Xizang Zangqing Energy Equipment Co., Ltd.: A tender announcement was officially issued for the EPC project covering design and construction of Phase I of the zero-carbon intelligent equipment base for the new energy industry of green hydrogen and green methanol in the Zangqing Industrial Park. It is understood that the project mainly includes: an annual output of 100 sets of 1,500 Nm³-2,000 Nm³ alkaline electrolyzers; a 500 MW/year production line for plateau-type PEM electrolyzers; a standardized production line for a 40,000 t/d methanol synthesis unit and components; an annual output of 120 sets of 500 kW integrated hydrogen-oxygen heat and power co-generation units; and an annual output of 50 sets of 500 kg/day skid-mounted integrated methanol hydrogen refueling station equipment. Renewable Green Hydrogen Energy (Inner Mongolia) Co., Ltd.: An announcement was issued on the signing of the EPC general contract for the Phase I, Stage I green ammonia project of the integrated 800,000 mt/year wind and solar power-hydrogen-ammonia project with Donghua Technology. It is understood that the contract was signed by both parties on March 5, with a contract value of 2.026 billion yuan (provisional estimate), and the construction period (mechanical completion) will run until June 18, 2028. Donghua Engineering Technology Co., Ltd. will mainly undertake the design, procurement, construction, operation assurance services, and guidance for startup and commissioning of the EPC project. Tangshan Haitai New Energy Technology Co., Ltd. : During the visit by the deputy secretary of the Abaqa Banner Committee in Inner Mongolia, the two sides further deepened cooperation on the 10 GW integrated wind and solar power-to-hydrogen project, working together to advance the project’s early commencement and commissioning. Maoming Binhai New Area Urban Investment Development Co., Ltd.: A public notice was issued on the shortlisted candidates for the construction of Phase I of the supporting road network project for the Green Chemical and Hydrogen Energy Industrial Park in Maoming Binhai New Area. The first shortlisted candidate was CCCC Fourth Harbor Engineering Co., Ltd., with a bid price of 98.210593 million yuan; the second shortlisted candidate was Hebei Xiangda Road & Bridge Engineering Co., Ltd., with a bid price of 98.23076 million yuan; and the third shortlisted candidate was Jiangxi Sitong Road & Bridge Construction Group Co., Ltd., with a bid price of 98.008929 million yuan. Fujian Tianchen Yaolong New Materials Co., Ltd.: A tender announcement was issued for the equipment procurement project for the hydrogen purification unit of the cyclohexanone technology upgrade and renovation project. It is understood that the project plans to procure one set of hydrogen purification unit equipment, with a maximum bid price of 7 million yuan. Inner Mongolia Juliyong Hydrogen New Energy Technology Co., Ltd.: Its new-type high-density, low-pressure solid-state hydrogen energy power R&D and industrialisation project was filed. The project will be constructed in Ordos City—Ordos Airport Logistics Park—Phase II, First Floor, Standardised Factory Buildings, Ordos Comprehensive Bonded Zone, Ejin Horo Banner, Ordos City, Inner Mongolia. The project is expected to be built in two phases, with a total investment of approximately 120 million yuan. It requires 10 million yuan in policy support funding, with Phase I investment of 40 million yuan and Phase II investment of 80 million yuan. The construction period is three years, and after completion, the project is expected to generate annual profit of 30 million yuan. Policy Review 1. At the press conference held during the fourth session of the 14th National People's Congress, Zheng Shanjie, Chairman of the National Development and Reform Commission, said that China would focus on developing the “six emerging pillar industries” and the “six future industries.” Among them, “green hydrogen energy and nuclear fusion energy” were included in the category of future industries. 2. The People's Government of Shandong Province issued the Implementation Plan on Supporting Jining in Accelerating Green and Low-Carbon Transformation and Building New Advantages in High-Quality Development. The document proposed supporting Jining in fostering and developing emerging industries and future industries such as hydrogen energy production, storage, and transportation, and supporting the construction of future industry acceleration parks; advancing R&D breakthroughs in key technologies such as hydrogen fuel cell vessels, building a leading inland new energy vessel manufacturing base in China; and supporting technological innovation and the promotion and application in fields such as hydrogen energy. 3. With the approval of the National Energy Administration, the Standardisation Technical Committee for the Hydrogen Energy Sector of the Energy Industry was established in Beijing. The establishment of the committee aims to improve the industry standard system, lead technological innovation, and regulate market order. Enterprise Updates Qinghang Times (Shenzhen) Technology Co., Ltd. : Qinghang Times was established on January 5, 2026, with a registered capital of 1 million yuan and legal representative He Rongjie. It was founded by a Tsinghua University master's and doctoral team, received support from Tsinghua innovation and entrepreneurship platforms such as Tsinghua i-Space and Tsinghua Chuang+, and was selected for the Sci-Tech Innovation Light “Future Sci-Tech Entrepreneur Program.” Through its technical solution combining liquid hydrogen storage and a high-temperature PEM hydrogen-electric coupling system, it increased aircraft driving range by more than 10 times and payload by 2–3 times. Recently, it completed seed-round financing worth several million yuan, with the investor undisclosed. Shenzhen Hydrogen Energy Co., Ltd.: Completed A+ round financing, with Shenzhen Energy Investment as the investor. Anhui Shuishui New Energy Technology Co., Ltd. : Anhui Shuishui Technology completed an A-round financing of over 100 million yuan, led by NIO Capital. This round of funding will be primarily used to fulfill large orders, increase R&D reserves, construct new factories, and support daily operations, in order to drive the integration and upgrading of the industry chain. SPIC Green Energy Co., Ltd.: held talks with Beijing Energy International Holding Co., Ltd., with both sides focusing on areas such as the construction of green electricity transmission channels into Beijing and pipeline transportation of green hydrogen, and conducting in-depth exchanges on deepening cooperation. Beijing Hydrosys Technology Co., Ltd. : helped successfully complete hydrogen refueling at Yunnan’s first integrated “PV–green electricity–hydrogen” refueling station. China Classification Society ​​​​​​​: supported the successful completion of the 16,136 TEU methanol dual-fuel container ship project. China Classification Society​​​​​​​​​​​​​​: the “COSCO 9802,” a single methanol-powered chemical tanker for which it carried out drawing approval and construction inspection, was successfully delivered. ​​Patent Applications​​ 1. Shanghai Institute of Ceramics, Chinese Academy of Sciences​​ (China) disclosed patent CN2025110028, developing a ceramic-based anion exchange membrane with a laboratory-tested lifespan of 80,000 hours. ​​2. Johnson Matthey​​ (UK) filed patent WO2025109876, disclosing a Fe-Ni-Mo ternary non-precious metal catalyst formulation with activity close to platinum-based materials. Technology Footprint/Technical Specifications​​ 1. A team from Xi’an Jiaotong University and Peking University jointly developed a new-type osmium-based catalyst, significantly improving the efficiency and economics of hydrogen production from AEM water electrolysis and supporting the large-scale deployment of low-cost green hydrogen. 2. Johnson Matthey and Syensqo achieved efficient recycling and reuse of platinum group metals and ionomers in PEM fuel cells and electrolyzers, substantially reducing the carbon footprint. 3.​​Research teams from the School of Electrical Engineering of Xi’an Jiaotong University and the State Key Laboratory of Electrical Materials and Electrical Insulation successfully developed the Ru/Ti3C2Ox@NF bifunctional electrocatalyst for seawater electrolysis. 4. The group standard Technical Specification for Wind and Solar Power, PV+ESS, and Green Electricity Coupled Electrolysis Hydrogen Production (No. T/CIEP 0272—2025) was released and implemented by the China Industrial Environmental Protection Promotion Association. Zhongneng Dayou Energy Technology Co., Ltd. successfully developed a 100 kW-class PEM electrolyzer hydrogen production multi-field coupling test device. 5. GKN Powder Metallurgy announced that it had developed a next-generation high performance, high-porosity, high-purity porous transport layer (HP-PTL) for proton exchange membrane (PEM) electrolysis.

Total rebar inventory stood at 8.2948 million mt this week, up 277,000 mt WoW, or 3.46% (previous: +11.33%), and up 363,200 mt from the same period of the previous lunar year, or 4.58% (previous: +4.6%).

[Magnesium Alloys Lead New Quality Productive Forces, Hydrogen Storage Goes Global + Vehicle Weight Reduction Reaches New Peaks] China’s magnesium alloy sector achieved two major breakthroughs, demonstrating the strong capabilities of indigenous innovation. On the one hand, a large-scale magnesium-based solid-state hydrogen storage device equipped with proprietary technology was successfully loaded at Shanghai Waigaoqiao Port and shipped to Malaysia, addressing longstanding pain points in traditional hydrogen storage and transportation and filling a gap in international maritime transport technology. On the other hand, the semi-solid injection-molded magnesium alloy seat frame assembly of FAW Hongqi was successfully installed, marking a key upgrade in vehicle lightweighting, with significant weight reduction achieved for each assembly. Spanning the two core fields of hydrogen storage and transportation and vehicle lightweighting, these achievements accelerated the scaled-up application of the magnesium alloy industry.