News Release: May 07, 2025
Dysprosium (III) Oxalate Price, Production, Latest News and Developments in 2025
The rare earth chemical compound Dysprosium (III) Oxalate has gained significant traction across global markets due to its relevance in magnetics, nuclear energy systems, and specialized glass manufacturing. As global supply chains evolve and industrial demand intensifies, monitoring the Dysprosium (III) Oxalate price trend and production News has become essential. For a detailed market report, refer to this comprehensive overview: Dysprosium (III) Oxalate price trend and production News.
Dysprosium (III) Oxalate Price Trend in Past Five Years and Factors Impacting Price Movements (2019-2024)
Between 2019 and 2024, Dysprosium (III) Oxalate prices witnessed significant volatility driven by geopolitical shifts, fluctuating demand in clean energy applications, and global supply chain disruptions. In 2019, the average market price stood at approximately $6800/MT. During this period, the compound remained stable in terms of production but faced mild cost pressure due to rising demand in the Asia-Pacific region, particularly China and South Korea.
In 2020, the outbreak of the COVID-19 pandemic disrupted mining operations and slowed logistics networks, particularly affecting rare earth mineral transportation. As a result, Dysprosium (III) Oxalate prices surged to around $7350/MT by Q3 2020. The sudden demand contraction from industries such as automotive and electronics did temper the price later in the year, leading to an average annual price of $7100/MT.
2021 marked a year of recovery and strong demand rebound. Green energy policies and increased electric vehicle production propelled consumption of rare earth compounds. Dysprosium (III) Oxalate price rose to $8100/MT in early 2021 and peaked at $8600/MT by the end of the year. The Chinese market accounted for more than 60% of global demand during this time, influenced by state subsidies and national strategic reserves.
In 2022, however, macroeconomic uncertainties, including inflationary pressure and global interest rate hikes, restrained industrial expansion. As a result, Dysprosium (III) Oxalate price retreated slightly to an average of $8250/MT. Nonetheless, demand from clean energy sectors and semiconductor manufacturing kept the market buoyant.
In 2023, technological developments and a strong emphasis on localized supply chains in Europe and the United States led to capacity additions. These expansions aimed to reduce reliance on Chinese exports. Consequently, global supply slightly improved, though not enough to substantially cool down prices. The compound’s price hovered around $8750/MT through the year.
Key influencing factors over the five-year period include:
- Expansion of rare earth extraction and processing in Australia and Africa.
- Chinese export policies and environmental regulations.
- The rise in demand from electric vehicles, wind turbines, and magnetic refrigeration.
- Increasing investment in recycling of rare earth materials.
Dysprosium (III) Oxalate Price Trend Quarterly Update in $/MT (2025)
Estimated quarterly prices for 2025 reflect steady upward momentum supported by robust demand and stable production levels. The following quarterly price outlook for 2025 is based on market expectations and upstream supply indicators:
- Q1 2025: $8900/MT
- Q2 2025: $9050/MT
- Q3 2025: $9150/MT
- Q4 2025: $9300/MT
This upward trend is attributed to expansion in green technology sectors and continuous procurement by key players securing long-term supply. Dysprosium (III) Oxalate price news indicates increased buying activity in Q2 2025 driven by restocking and raw material procurement by European manufacturers.
Global Dysprosium (III) Oxalate Import-Export Business Overview (2025)
The global Dysprosium (III) Oxalate trade landscape has undergone significant transformation over the past few years. In 2025, the market is characterized by increasing diversification of supply sources and more aggressive import strategies from developed economies.
China remains the leading producer and exporter of Dysprosium (III) Oxalate. The country’s dominance stems from its large-scale mining operations, refined manufacturing capacity, and government-backed subsidies for rare earth materials. In 2024, China accounted for over 55% of the world’s Dysprosium (III) Oxalate production. However, in 2025, other regions such as Australia, Myanmar, and select African nations have increased their output. Australia’s investment in downstream processing has enhanced its capability to export value-added rare earth compounds, including oxalates.
On the import side, countries in the European Union and North America have boosted their imports amid a strategic move to secure critical materials for electric vehicles and defense sectors. Dysprosium (III) Oxalate sales volume has seen a notable rise in Germany, France, and the United States, driven by increased funding toward renewable energy technologies and domestic magnet manufacturing.
India and South Korea also remain active participants in the Dysprosium (III) Oxalate trade, primarily as importers. South Korea’s electronics and display industries rely heavily on stable imports, while India’s rapid industrialization continues to drive compound demand. Japanese firms, while traditionally relying on Chinese exports, have recently diversified sourcing, with shipments now arriving from both Australia and Southeast Asia.
The Dysprosium (III) Oxalate production landscape is evolving with investments in extraction technology. Several new entrants have adopted solvent extraction and advanced precipitation methods, increasing purity and yield efficiency. In 2025, Dysprosium (III) Oxalate production is expected to increase by 4.8% year-on-year, bolstered by projects in Central Africa and pilot facilities in Canada.
Trade routes have also undergone change. Sea-based shipments remain dominant, but due to geopolitical concerns in the South China Sea, there has been an uptick in overland shipments via the China-Europe Railway Express. In particular, the Belt and Road Initiative has facilitated easier movement of rare earth oxalates to Eastern Europe and Central Asia.
Trade policies in 2025 are shifting toward tighter scrutiny. The U.S. and EU have introduced compliance guidelines to trace the origin of rare earth materials, aimed at curbing illegal mining and environmental degradation. These regulations are expected to reshape the market and influence Dysprosium (III) Oxalate sales volume from unofficial suppliers.
The Dysprosium (III) Oxalate price news in international trade reflects tight margins for importers amid rising freight costs and customs duties. Exporters from non-Chinese regions, however, benefit from increasing market access and premium pricing. Meanwhile, intra-Asia trade continues to grow, particularly with Vietnam and Thailand becoming emerging distribution hubs.
In terms of volume, the total Dysprosium (III) Oxalate sales volume globally is projected to reach 950 metric tons in 2025, reflecting a growth of 6.5% from the previous year. Most of this volume is consumed by permanent magnet manufacturers, followed by specialized chemical processing industries and academic research institutions.
Export pricing remains higher for refined, high-purity grades used in laser and nuclear applications, whereas technical-grade Dysprosium (III) Oxalate is traded at slightly lower prices. Export offers in Q2 2025 range from $8900/MT to $9600/MT depending on grade and destination.
Emerging trends in Dysprosium (III) Oxalate news point toward increased bilateral agreements between mining-rich nations and technology manufacturers. Strategic stockpiling efforts are visible in South Korea and Japan, while European Union nations continue to promote recycling and substitution research to reduce dependency on imported rare earths.
To conclude, the Dysprosium (III) Oxalate market in 2025 remains vibrant and dynamic. Strong industrial demand, a shift in geopolitical alliances, evolving trade routes, and a resilient price trend indicate a healthy outlook for producers and traders alike.
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Dysprosium (III) Oxalate Production Trends by Geography
Dysprosium (III) Oxalate production has traditionally been concentrated in regions with access to rare earth mineral reserves, advanced processing infrastructure, and supportive regulatory frameworks. In 2025, global production has become increasingly diversified, with significant contributions from Asia-Pacific, North America, Africa, and select parts of Europe. This section examines the geographical distribution and trends shaping Dysprosium (III) Oxalate production globally.
China
China remains the dominant force in Dysprosium (III) Oxalate production, accounting for over half of global output in 2025. The country benefits from rich rare earth ore deposits, particularly in provinces like Inner Mongolia, Sichuan, and Jiangxi. Government-supported rare earth industrial parks and vertically integrated supply chains have enabled efficient mining, separation, and compound processing. Most of the Dysprosium extracted is processed into oxalates domestically, ensuring China’s stronghold in global exports. However, the Chinese government’s recent tightening of environmental regulations and production quotas has moderated output growth.
Australia
Australia has emerged as a significant producer of rare earth elements, including Dysprosium (III) Oxalate, thanks to its abundant mineral resources and investment in advanced processing. Projects in Western Australia, such as those operated by local and foreign partnerships, have started to produce refined oxalate compounds for export. In 2025, Australia’s production volume has increased by approximately 15% year-on-year, with a focus on supplying Western markets that seek alternatives to Chinese sources.
United States
The U.S. has prioritized the revival of domestic rare earth production due to concerns over strategic material security. While Dysprosium reserves in the U.S. are relatively lower than those in China or Australia, efforts have been made to develop refining capabilities and downstream processing. Pilot facilities in California and Texas are producing limited quantities of Dysprosium (III) Oxalate, with government backing through research grants and defense sector partnerships.
India
India’s production of Dysprosium (III) Oxalate remains modest, but there has been progress in 2025 due to investments in mineral exploration and rare earth separation plants. India’s reserves, particularly in the coastal states, are being utilized more efficiently with the help of new public-private collaborations. While much of the production is consumed domestically, there is potential for export growth in the near future.
Africa
Countries such as Madagascar and the Democratic Republic of Congo have become important sources of rare earth raw materials. Though local infrastructure remains underdeveloped, international mining firms have established joint ventures for ore extraction. In 2025, Africa’s role is primarily that of a raw material supplier, but there are ongoing plans to expand refining and oxalate production on the continent to capture more value within regional economies.
Europe
Europe has taken steps to reduce its dependence on imports by supporting recycling and small-scale rare earth processing. Scandinavian nations, in particular, have invested in sustainable mining and are testing technologies for rare earth extraction from secondary sources. Production of Dysprosium (III) Oxalate in Europe is still limited but expected to rise through 2026 as pilot programs scale up.
Southeast Asia
Vietnam, Thailand, and Malaysia are becoming minor but growing producers of Dysprosium (III) Oxalate. Leveraging their rare earth deposits and low-cost labor markets, these countries are beginning to establish themselves in the processing segment. Investment from Japanese and South Korean firms has been instrumental in setting up local operations that meet export-grade quality standards.
In summary, the production of Dysprosium (III) Oxalate is gradually shifting from being highly centralized to becoming more geographically diverse. While China retains its leadership, other regions are scaling up rapidly, driven by geopolitical strategies, environmental policies, and the need for secure supply chains.
Dysprosium (III) Oxalate Market Segmentation
Segments:
- By Purity Level
- By Application
- By End-Use Industry
- By Geography
- By Form (Powder, Granules)
1. By Purity Level
Dysprosium (III) Oxalate is typically segmented based on its purity—technical grade and high-purity grade. Technical grade is used in general industrial applications such as ceramics and metallurgy. High-purity grade, often exceeding 99.9% purity, is used in nuclear technologies, electronics, and specialty magnet manufacturing.
In 2025, the high-purity segment leads the market due to increasing demand from advanced electronics and clean energy sectors. Manufacturers prioritize high-purity Dysprosium (III) Oxalate for use in magnetic cooling systems and precision optical devices, where impurity levels must be minimal to ensure performance and safety. The rising production of high-efficiency motors and sensors in electric vehicles has also boosted the demand for high-purity oxalates.
2. By Application
Applications of Dysprosium (III) Oxalate include permanent magnets, nuclear reactors, lighting, and laser materials. Among these, permanent magnets are the leading application area in 2025. Dysprosium’s role in enhancing thermal resistance and magnetic strength makes it a crucial component in neodymium-iron-boron (NdFeB) magnets used in electric vehicles and wind turbines.
Nuclear applications are the second most prominent segment. Dysprosium compounds are utilized in control rods due to their high neutron absorption capacity. As nuclear power generation gains global support as a low-carbon energy source, this segment is experiencing stable growth.
The lighting and laser materials segment, while smaller, is showing moderate growth as demand rises for specialized lasers and high-luminosity lighting used in industrial and medical settings.
3. By End-Use Industry
Key end-use industries include automotive, renewable energy, defense, electronics, and metallurgy. The automotive industry is currently the most influential end-user, driven by the expanding market for electric vehicles. Manufacturers require stable supplies of Dysprosium (III) Oxalate for advanced drive motors and regenerative braking systems.
The renewable energy sector, particularly wind power, also consumes significant volumes of Dysprosium (III) Oxalate in turbine generators. Defense applications, including guided systems and stealth technologies, contribute to niche but high-value demand.
The electronics industry relies on the compound for producing components in mobile devices, LEDs, and display technologies. Meanwhile, metallurgy and chemical processing use Dysprosium (III) Oxalate for alloy enhancements and research-grade reactions.
4. By Geography
Geographical segmentation shows dominance of the Asia-Pacific region, followed by North America and Europe. China, South Korea, and Japan are the key consumers due to their large electronics and automotive industries. North America, particularly the U.S., is focusing on increasing domestic consumption to reduce reliance on imports. Europe is gradually increasing demand, especially from Germany and France, where green energy and high-performance manufacturing are expanding.
5. By Form
Dysprosium (III) Oxalate is available in various physical forms, including powder and granules. Powder form remains dominant due to its ease of integration in chemical reactions and sintering processes. It is particularly favored in magnet manufacturing and laboratory-scale synthesis. Granules are used in specialized applications that require reduced dust and improved handling during bulk processing.
To summarize, the Dysprosium (III) Oxalate market is segmented across multiple dimensions, with the high-purity, permanent magnet, and automotive sectors leading the way. As technological advancements and sustainability goals shape industrial requirements, demand for specialized grades and applications is expected to grow steadily across global markets.