News Release : Global Ceric Oxide (Cerium(IV) oxide) Production Analysis, import-export, Price Update: 2025 

News Release: May 07, 2025 

Ceric Oxide (Cerium(IV) oxide) Price, Production, Latest News and Developments in 2025 

The global Ceric Oxide (Cerium(IV) oxide) market has been experiencing dynamic shifts, largely influenced by fluctuations in raw material supply, demand from the polishing and catalyst industries, and geopolitical trade decisions. According to the latest Ceric Oxide (Cerium(IV) oxide) price trend and production News, 2025 has been a pivotal year, reflecting both recovery from past supply chain challenges and the emergence of new technological applications in the electronics and green energy sectors. With ongoing investments and developments across Asia-Pacific and North America, the market is showing signs of gradual stabilization and growth. 

Ceric Oxide (Cerium(IV) oxide) Price Trend in Past Five Years and Factors Impacting Price Movements (2019–2024) 

The Ceric Oxide (Cerium(IV) oxide) price trend from 2019 to 2024 reveals a pattern shaped by macroeconomic and industrial developments. In 2019, prices averaged around $6,300/MT, relatively stable due to balanced supply from Chinese producers and moderate global demand. By 2020, the price dipped slightly to $6,100/MT amid decreased industrial activity due to the COVID-19 pandemic. 

In 2021, as global manufacturing started rebounding, prices rose to $6,800/MT, supported by increased demand from the semiconductor and glass polishing sectors. However, this rise was short-lived as 2022 saw logistical bottlenecks and rising energy costs pushing prices up to $7,500/MT. The Ukraine-Russia conflict also indirectly impacted rare earth markets by increasing production costs and rerouting supply chains. 

The year 2023 recorded the peak of the last five years, with Ceric Oxide (Cerium(IV) oxide) prices reaching around $8,200/MT, driven by robust demand in EV manufacturing and the chemical industry. However, oversupply from Chinese producers and a temporary reduction in export tariffs caused a slight market correction by the end of 2023. 

In early 2024, prices hovered around $7,700/MT but fell to $7,300/MT by Q4 due to reduced demand in the glass and catalyst segments. Moreover, increased recycling and substitution technologies began to influence the long-term Ceric Oxide (Cerium(IV) oxide) price trend. These factors, coupled with global economic slowdown and shifts in import-export regulations, have played a significant role in the pricing dynamics over the last half-decade. 

Overall, the Ceric Oxide (Cerium(IV) oxide) price trend reflects a market responsive to technological shifts, supply chain resilience, and raw material accessibility. A key influencer continues to be the Chinese market, accounting for more than 80% of global production, which directly impacts the Ceric Oxide (Cerium(IV) oxide) sales volume and its pricing behavior across continents. 

Ceric Oxide (Cerium(IV) oxide) Price Trend Quarterly Update in $/MT (2024–2025) 

Here is the estimated quarterly Ceric Oxide (Cerium(IV) oxide) price news update from Q1 2024 through Q2 2025: 

• Q1 2024: $7,700/MT 

• Q2 2024: $7,500/MT 

• Q3 2024: $7,400/MT 

• Q4 2024: $7,300/MT 

• Q1 2025: $7,600/MT (slight recovery due to seasonal demand rise) 

• Q2 2025: $7,850/MT (driven by new contracts from the electronics industry and increased global purchases) 

Forecasts for H2 2025 suggest a moderate price increase, reaching up to $8,000/MT by Q4 if demand from EV and renewable energy sectors strengthens. However, surplus inventory and slower-than-expected rollout of polishing materials in Asia could suppress further spikes. 

Global Ceric Oxide (Cerium(IV) oxide) Import-Export Business Overview 

The Ceric Oxide (Cerium(IV) oxide) trade landscape has undergone considerable changes over the past few years, with evolving policies, growing demand from clean energy sectors, and the reorientation of global supply chains post-pandemic. In 2025, the global Ceric Oxide (Cerium(IV) oxide) import-export business is being reshaped by sustainability goals and regional investment strategies. 

China continues to dominate Ceric Oxide (Cerium(IV) oxide) production, contributing nearly 85% of the world’s supply. The country has invested in both raw material extraction and advanced oxide refining technologies, enabling it to maintain pricing leverage globally. China’s export volumes surged in late 2024 due to decreased domestic demand and relaxed export restrictions, with nearly 30,000 MT shipped to various markets. 

India, Japan, and South Korea remain major importers of Ceric Oxide (Cerium(IV) oxide), utilizing it in glass polishing, auto catalysts, and electronics. India’s import volume increased by 11% in Q1 2025, reaching 2,100 MT, while Japan focused on securing supply contracts for its growing EV battery recycling sector. 

In North America, the United States has been aggressively reducing dependency on Chinese imports. The Biden administration’s clean tech strategy and investment in rare earth mining operations in Nevada have boosted domestic Ceric Oxide (Cerium(IV) oxide) production capacity by 14% over the past year. While the U.S. still imported around 5,000 MT in 2024, this figure is expected to decline in 2025 due to local production expansions and trade pacts with Australia and Canada. 

The European Union’s Green Deal policies are also impacting Ceric Oxide (Cerium(IV) oxide) import trends. France and Germany are working towards a circular economy model, enhancing recycling infrastructure that allows recovery of cerium from used catalysts and electronics. Consequently, their direct import needs have started to plateau, with overall EU imports estimated at 8,500 MT in 2024. 

Southeast Asia, particularly Vietnam and Thailand, are emerging as new processing hubs for Ceric Oxide (Cerium(IV) oxide), benefiting from relaxed environmental regulations and lower operating costs. These countries have started importing intermediate rare earth concentrates from Africa, processing them into usable oxides for export to industrialized markets. This shift may contribute to a long-term redistribution of Ceric Oxide (Cerium(IV) oxide) sales volume globally. 

In terms of Ceric Oxide (Cerium(IV) oxide) production, newer facilities in Australia and Brazil are beginning to scale operations. Australia, with its rich monazite sand reserves, has become a strategic supplier to Western countries, though its total production is still less than 10% of China’s. These developments are diversifying the supply base and creating competition that could influence long-term Ceric Oxide (Cerium(IV) oxide) price trend. 

Technology also plays a significant role. With the advancement of nanotechnology and smart materials, high-purity Ceric Oxide (Cerium(IV) oxide) is increasingly demanded for specialized coatings and fuel cell applications. This high-grade oxide commands prices 15–20% higher than standard grades, thereby influencing average Ceric Oxide (Cerium(IV) oxide) price news in international markets. 

Looking ahead, 2025 is expected to witness moderate growth in Ceric Oxide (Cerium(IV) oxide) production, with total global output reaching approximately 46,000 MT by year-end, up from 42,500 MT in 2024. Demand growth is forecasted at around 6%, with primary consumption regions being Asia-Pacific, North America, and Western Europe. 

Trade policies, recycling technologies, and advancements in downstream industries will continue to impact the Ceric Oxide (Cerium(IV) oxide) price trend and Ceric Oxide (Cerium(IV) oxide) sales volume. Governments are now prioritizing sustainability and supply chain security, which may reduce price volatility in the coming years. 

To access a detailed report and request a sample of the latest Ceric Oxide (Cerium(IV) oxide) market trends, visit: https://datavagyanik.com/reports/global-ceric-oxide-ceriumiv-oxide-market/ 

Ceric Oxide (Cerium(IV) oxide) Production Trends by Geography 

The global production landscape of Ceric Oxide (Cerium(IV) oxide) has undergone substantial transformation in recent years, with major changes in regional output, government policies, and technological investments. As of 2025, production remains heavily concentrated in Asia, with increasing contributions from select regions in North America, Europe, and Oceania. 

China remains the dominant player in Ceric Oxide (Cerium(IV) oxide) production, contributing nearly 85% of the global supply. The country’s advantage lies in its abundant reserves of bastnasite and monazite, which are key raw materials for cerium extraction. Chinese companies have streamlined refining technologies and operate under government-backed export quotas. Production facilities are primarily located in Inner Mongolia, Sichuan, and Jiangxi provinces. Despite environmental concerns and past clampdowns on illegal mining, China continues to lead global output due to infrastructure maturity, lower processing costs, and government incentives. 

India is expanding its footprint in Ceric Oxide (Cerium(IV) oxide) production, supported by initiatives from both public and private sectors. The country has deposits of rare earth minerals in the coastal states of Odisha and Tamil Nadu. Though still dependent on imports for high-purity oxides, domestic production is gradually increasing due to investments in monazite processing and the development of integrated rare earth value chains. India’s focus is on establishing self-reliant supply chains to support its electronics and automotive industries. 

Australia has emerged as a significant alternative supplier outside China. Known for its large reserves of rare earth minerals, particularly in Western Australia and the Northern Territory, the country is investing in upstream and downstream rare earth processing. Australian firms are exporting mixed rare earth concentrates, some of which are processed domestically, while others are sent to Southeast Asia for conversion to Ceric Oxide (Cerium(IV) oxide). Australia’s production is focused on environmentally sustainable practices, making it a preferred partner for Western economies. 

The United States has been working aggressively to re-establish its domestic production capabilities. Although the country has notable reserves in states like California and Nevada, production has been historically limited due to environmental regulations and competition from cheaper Chinese imports. In 2025, several projects have reached commercial scale, supported by federal funding and strategic partnerships with defense and technology companies. The U.S. aims to develop refining infrastructure to supply domestic Ceric Oxide (Cerium(IV) oxide) demand, particularly for clean energy and military applications. 

Canada is also entering the global production scene with exploration projects in Quebec and the Northwest Territories. While not yet a major producer, Canadian companies are exploring long-term investments in rare earth extraction and oxide processing, aiming to establish secure supply routes for North America and Europe. 

European Union countries, particularly France, Germany, and Sweden, have limited raw material availability but are focusing on recovery and recycling methods to produce Ceric Oxide (Cerium(IV) oxide). Recycling from used catalysts, glass waste, and electronics has become a central strategy. The EU is investing in urban mining and advanced separation technologies to reduce reliance on imports. 

Japan and South Korea lack sufficient natural reserves but have developed highly advanced processing technologies. These nations import rare earth concentrates and process them into value-added products including Ceric Oxide (Cerium(IV) oxide). Their industries focus on high-purity grades used in electronics, semiconductors, and display technologies. Both countries are also investing in circular economy strategies to recover cerium from end-of-life products. 

Brazil and several African countries are emerging as potential producers due to untapped rare earth deposits. Brazil has monazite reserves in its coastal regions and is attracting investment from both domestic and foreign entities. Similarly, nations such as Madagascar and South Africa are evaluating the feasibility of large-scale extraction and processing projects. 

Overall, while China continues to dominate Ceric Oxide (Cerium(IV) oxide) production, the trend in 2025 is toward diversification. Countries across North America, Europe, and Oceania are strengthening domestic production capabilities to reduce dependency and meet rising demand. These regional efforts are expected to shift the global production map over the next decade. 

Ceric Oxide (Cerium(IV) oxide) Market Segmentation 

Major Segments of Ceric Oxide (Cerium(IV) oxide) Market: 

1. By Application: 

1. Glass Polishing 

2. Automotive Catalysts 

3. Electronics and Semiconductors 

4. Ceramics and Coatings 

5. Renewable Energy Applications 

6. Chemical Catalysis 

2. By Grade: 

1. Technical Grade 

2. High Purity Grade 

3. Ultrapure Grade 

3. By End Use Industry: 

1. Automotive 

2. Electronics 

3. Energy 

4. Construction 

5. Industrial Manufacturing 

4. By Region: 

1. Asia-Pacific 

2. North America 

3. Europe 

4. Latin America 

5. Middle East and Africa 

Explanation of Leading Segments 

Among applications, glass polishing remains the leading segment. Ceric Oxide (Cerium(IV) oxide) is highly effective in polishing applications due to its abrasive properties and chemical reactivity. It is widely used in the manufacturing of LCDs, precision optical components, and solar glass. Demand for flat-panel displays and high-quality lenses continues to support this segment’s dominance. The Asia-Pacific region, particularly China, Japan, and South Korea, leads in consumption due to the concentration of electronics and display manufacturing facilities. 

Automotive catalysts form the second-largest application segment. Ceric Oxide (Cerium(IV) oxide) is essential in catalytic converters, acting as an oxygen buffer to reduce emissions from internal combustion engines. Despite the growing shift to electric vehicles, this segment remains vital in emerging economies where combustion engines are still widely used. Furthermore, hybrid vehicle production continues to use catalytic systems, sustaining demand for Ceric Oxide (Cerium(IV) oxide) in this segment. 

The electronics and semiconductors segment is growing rapidly. Ceric Oxide (Cerium(IV) oxide) is used in high-k dielectric materials and memory chips, driven by demand for faster, smaller, and more energy-efficient devices. High-purity and ultrapure grades are especially important in this segment. Japan, South Korea, and Taiwan are major consumers, with the United States and Germany expanding their role in semiconductor manufacturing. 

In terms of grade, technical grade dominates the market by volume, particularly in glass and catalyst applications. However, the high purity and ultrapure grades are experiencing higher growth rates due to increasing demand from the electronics and clean energy sectors. These grades require advanced processing technologies, which only a few countries currently possess. 

The energy sector, especially renewable energy, represents an emerging segment. Ceric Oxide (Cerium(IV) oxide) is used in solid oxide fuel cells and as a catalyst in hydrogen production. As green hydrogen and alternative energy systems gain traction, this segment is expected to see accelerated growth in the coming years. 

Regionally, the Asia-Pacific market leads in both consumption and production. The presence of electronics, automotive, and glass manufacturing hubs in China, India, South Korea, and Japan supports sustained demand. North America is witnessing a surge in investment in rare earth processing and clean energy technologies, pushing Ceric Oxide (Cerium(IV) oxide) consumption higher. In Europe, regulatory mandates and industrial innovation are driving demand, particularly in high-purity applications and recycling-based production. 

Overall, the Ceric Oxide (Cerium(IV) oxide) market is characterized by strong application diversity and region-specific strengths. While traditional segments like polishing and catalysts remain dominant, emerging applications in electronics and energy are shaping the future demand landscape. This ongoing diversification across both usage and geography positions the market for continued evolution through 2030.