Uranium fell to 76.40 USD/Lbs on December 1, 2025, down 0.07% from the previous day. Over the past month, Uranium's price has fallen 5.45%, and is down 1.80% compared to the same time last year, according to trading on a contract for difference (CFD) that tracks the benchmark market for this commodity. Uranium - values, historical data, forecasts and news - updated on December of 2025.

Graph and download economic data for Global price of Uranium (PURANUSDM) from Jan 1990 to Jun 2025 about uranium, World, and price.

In June 2025, the global average price per pound of uranium stood at roughly 59.58 U.S. dollars. Uranium prices peaked in June 2007, when it reached 136.22 U.S. dollars per pound. The average annual price of uranium in 2024 was 69.69 U.S. dollars per pound. Global uranium production Uranium is a heavy metal, and it is most commonly used as a nuclear fuel. Nevertheless, due to its high density, it is also used in the manufacturing of yacht keels and as a material for radiation shielding. Over the past 50 years, Kazakhstan and Uzbekistan together dominated uranium production worldwide. Uranium in the future Since uranium is used in the nuclear energy sector, demand has been constantly growing within the last years. Furthermore, the global recoverable resources of uranium increased between 2015 and 2021. Even though this may appear as sufficient to fulfill the increasing need for uranium, it was forecast that by 2035 the uranium demand will largely outpace the supply of this important metal.

View monthly updates and historical trends for Uranium Spot Price. Source: International Monetary Fund. Track economic data with YCharts analytics.

The average annual price for one pound of uranium was ******U.S. dollars in 2024. This is the highest annual average since 2007, and comes in the wake of greater fuel demand as the global economy began recovering from the coronavirus pandemic as well as the energy crisis.

Uranium Prices - Historical chart and current data through 2025.

Monthly and long-term uranium price data (US$/lb): historical series and analyst forecasts curated by FocusEconomics.

Price-Earnings-Ratio Time Series for Uranium Energy Corp. Uranium Energy Corp., together with its subsidiaries, engages in exploration, pre-extraction, extraction, and processing of uranium and titanium concentrates properties in the United States, Canada, and the Republic of Paraguay. The company was formerly known as Carlin Gold Inc. and changed its name to Uranium Energy Corp. in January 2005. The company was incorporated in 2003 and is headquartered in Corpus Christi, Texas.

According to Cognitive Market Research, the global Enriched Uranium market size was USD 13214.5 million in 2024. It will expand at a compound annual growth rate (CAGR) of 4.00% from 2024 to 2031.

North America held the major market share for more than 40% of the global revenue with a market size of USD 5285.80 million in 2024 and will grow at a compound annual growth rate (CAGR) of 2.2% from 2024 to 2031.
Europe accounted for a market share of over 30% of the global revenue with a market size of USD 3964.35 million.
Asia Pacific held a market share of around 23% of the global revenue with a market size of USD 3039.34 million in 2024 and will grow at a compound annual growth rate (CAGR) of 6.0% from 2024 to 2031.
Latin America had a market share of more than 5% of the global revenue with a market size of USD 660.73 million in 2024 and will grow at a compound annual growth rate (CAGR) of 3.4% from 2024 to 2031.
Middle East and Africa had a market share of around 2% of the global revenue and was estimated at a market size of USD 264.29 million in 2024 and will grow at a compound annual growth rate (CAGR) of 3.7% from 2024 to 2031.
The UHF Technology is the dominant segment in the Enriched Uranium Market due to its superior range and reliability in communication and tracking systems

Market Dynamics of Enriched Uranium Market

Key Drivers for Enriched Uranium Market

Rising Demand for Clean and Sustainable Energy to Boost Market Growth: The growing focus on reducing greenhouse gas emissions and achieving carbon neutrality is significantly driving the demand for enriched uranium. Nuclear power, which relies on enriched uranium, is recognized as a reliable and clean energy source with minimal carbon emissions compared to fossil fuels. Many countries are shifting their energy mix towards nuclear energy to meet international climate goals and rising energy demands. This transition is further fueled by increasing investments in nuclear power plants, particularly in regions like Asia-Pacific and Europe, where energy security and sustainability are paramount concerns. For instance, In July 2021, Orano SA announced a strategic partnership with the French Alternative Energies and Atomic Energy Commission (CEA) to collaborate on the development of new technologies for the decommissioning of nuclear facilities and the management of radioactive waste

Technological Advancements in Uranium Enrichment Processes to Drive Market Growth: Technological innovations in uranium enrichment methods are enhancing efficiency, reducing production costs, and increasing the output of enriched uranium. Advancements like centrifuge technology and laser isotope separation are enabling more precise and cost-effective enrichment processes, driving the market forward. These technological improvements are not only benefiting existing nuclear power facilities but also encouraging new investments in uranium enrichment facilities. As a result, companies and governments are better equipped to meet the growing demand for enriched uranium, ensuring long-term energy supply security while maintaining operational cost-efficiency.

Key Restraints for Enriched Uranium Market

Stringent Regulations and Safety Concerns, will Limit Market Growth: The enriched uranium market faces challenges due to stringent regulations and safety concerns surrounding nuclear energy. Governments and international organizations impose rigorous safety standards and non-proliferation protocols to prevent misuse and ensure the safe handling, transportation, and storage of enriched uranium. Compliance with these regulations often leads to high operational costs and lengthy approval processes for nuclear power projects. Moreover, public concerns about nuclear accidents, radioactive waste management, and environmental risks further hinder market growth. These factors collectively slow down the adoption of nuclear energy, limiting the expansion of the enriched uranium market.

Key Trends for Enriched Uranium Market

Transition to High-Assay Low-Enriched Uranium (HALEU): Innovative reactor designs, including small modular reactors (SMRs), necessitate HALEU (enriched between 5% and 20%). This shift is increasing the demand for elevated enrichment levels, thereby generating new prospects for market participants.

Growing Collaborations and Strategic Partnerships: Businesses and governmental entities are establishing joint ventures to secure uranium supp...

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Uranium Market Size 2025-2029

The uranium market size is forecast to increase by USD 2.18 billion at a CAGR of 8.2% between 2024 and 2029.

The market is characterized by the rising adoption of uranium in nuclear weapons and nuclear reactors, presenting significant growth opportunities. This is due to the escalating reliance on renewable energy, and the rise in uranium mining initiatives. Uranium's role as a primary fuel source in nuclear energy generation continues to expand, driven by the increasing demand for clean energy and the depletion of conventional energy resources. However, the market faces substantial challenges due to the high initial and production costs of uranium. These costs, coupled with the volatility in uranium prices, pose significant challenges for market participants.
Additionally, investments in research and development of advanced nuclear technologies, such as small modular reactors and nuclear fusion, could offer potential solutions to the high production costs and supply constraints, positioning these companies at the forefront of the evolving market landscape. To capitalize on the growth opportunities and navigate these challenges effectively, companies must focus on optimizing production costs, exploring alternative sources of uranium, and collaborating with industry peers to share best practices and resources. The market is witnessing significant growth due to the increasing adoption of uranium in nuclear weaponry and nuclear reactors.

What will be the Size of the Uranium Market during the forecast period?

Explore in-depth regional segment analysis with market size data - historical 2019-2023 and forecasts 2025-2029 - in the full report.
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The market is characterized by a complex interplay of factors, including nuclear emergency response, fusion power research, and nuclear weapons proliferation and disarmament. Small modular reactors and advanced reactors are gaining traction as solutions for nuclear energy security, while radioactive tracer and isotope production are essential in various industries, from agriculture to medical imaging. Nuclear fuel reprocessing and spent fuel management are critical aspects of nuclear arms control and non-proliferation efforts. Breeder reactors and nuclear forensics contribute to nuclear security, while radiation therapy, protection, and nuclear medicine imaging advance healthcare applications.
Nuclear energy sustainability is a pressing concern, with the need for effective radioactive waste storage and transportation solutions. The Nuclear Security Summit underscores the importance of addressing nuclear terrorism risks. Nuclear magnetic resonance is a versatile technology with applications in various sectors, from materials science to medical research. Additionally, the production cost of uranium and the prices in the market significantly influence the profitability of nuclear power plants.

How is this Uranium Industry segmented?

The uranium industry research report provides comprehensive data (region-wise segment analysis), with forecasts and estimates in 'USD million' for the period 2025-2029, as well as historical data from 2019-2023 for the following segments.

End-user

  Energy
  Military
  Others


Source

  Primary
  Secondary


Application

  Industrial counterweights
  Radiation shielding
  Medical isotopes


Geography

  North America

    US
    Canada
    Mexico


  Europe

    Germany
    Russia
    Ukraine


  APAC

    Australia
    China
    India


  Rest of World (ROW)

By End-user Insights

The energy segment is estimated to witness significant growth during the forecast period. Uranium plays a crucial role in nuclear power generation, supplying fuel for electricity production in power plants around the world. The global shift towards cleaner energy sources and the rising awareness of carbon footprint reduction have fueled the demand for nuclear power. Nuclear power economics have gained significance, leading to increased investment in uranium production and conversion to uranium hexafluoride for enrichment. Uranium mining continues to be a critical aspect of the industry, with safety, regulation, and sustainability being key considerations. Nuclear power plants require stringent safety measures, including radiation detection and shielding, to ensure reliable operation. Nuclear fuel services provide essential support, from fabrication and licensing to decommissioning and waste management.

Uranium oxide is used in fuel assemblies, while uranium metal is essential for nuclear engineering and innovation. Nuclear power infrastructure development, including construction and technology advancements, continues to drive market growth. Despite the challenges of nuclear power regulation and the presence of nuclear weapons, the industry remains committed to nuclear power safety and security. Uranium enrichment and

According to Cognitive Market Research, the global uranium mining market size was USD 8548.2 million in 2024. It will expand at a compound annual growth rate (CAGR) of 4.50% from 2024 to 2031.

North America held the major market share for more than 40% of the global revenue with a market size of USD 3419.28 million in 2024 and will grow at a compound annual growth rate (CAGR) of 2.7% from 2024 to 2031.
Europe accounted for a market share of over 30% of the global revenue with a market size of USD 2564.46 million.
Asia Pacific held a market share of around 23% of the global revenue with a market size of USD 1966.09 million in 2024 and will grow at a compound annual growth rate (CAGR) of 6.5% from 2024 to 2031.
Latin America had a market share of more than 5% of the global revenue with a market size of USD 427.41 million in 2024 and will grow at a compound annual growth rate (CAGR) of 3.9% from 2024 to 2031.
Middle East and Africa had a market share of around 2% of the global revenue and was estimated at a market size of USD 170.96 million in 2024 and will grow at a compound annual growth rate (CAGR) of 4.2% from 2024 to 2031.
The underground mining category is the fastest growing segment of the uranium mining industry

Market Dynamics of Uranium Mining Market

Key Drivers for Uranium Mining Market

Growing Demand for Nuclear Energy to Boost Market Growth

Nuclear power reactors can emit radiation, but it is less than that produced by coal-fired power plants. A ton of uranium is about equivalent to 1,000 tons of coal, 42,000 gallons of oil, or 17 million cubic feet of natural gas for one kilowatt of electricity generation. As a result, just a tiny amount of uranium is required for mining, which has a lower environmental impact than mining fossil fuels. During the predicted period, the need for clean energy technologies will expand, resulting in more nuclear reactor construction. This, in turn, is likely to drive the market throughout the forecast period. The growing focus on clean energy technology is significantly driving market growth. To minimize carbon emissions, there is an increasing need for clean energy solutions such as nuclear power around the world. Nuclear power stations do not emit CO2, methane, or other hazardous gases. For instance, According to the IEA, energy-related CO2 emissions grew globally by 6% in 2021 compared to 2020 due to rising global energy demand and widespread usage of fossil fuels.

Technological Advancements to Drive Market Growth

Technological advancements are impacting market expansion. The digitization of mining operations has become a major trend in the global industry. Stringent safety standards for uranium mining activities have influenced operating and capital expenses. Employee safety, as well as machine and process productivity, have become increasingly important in the mining business. Automation facilitates the collection of real-time data for process monitoring and decision-making. For example, Cameco Corp. uses robots, artificial intelligence, and enhanced process control to make its operations safer and more efficient. On-site underground mining operations use automation solutions such as remotely operated systems to operate equipment and machinery and eliminate safety risks.

Restraint Factor for the Uranium Mining Market

The Competition for Nuclear Energy Will Limit Market Growth

Nuclear power may face competition from alternative energy sources, limiting market expansion. Renewable energy sources include geothermal, solar, wind, hydropower, and biomass. According to the International Energy Agency, renewables and natural gas accounted for 28% and 24% of total energy generation in 2020, respectively. Renewables' popularity has grown dramatically all over the world. The use of sustainable energy sources for power is increasing. As a result, the need for renewable energy sources has grown rapidly. According to the IEA, nuclear power's contribution to total electricity output fell by around 3 GW globally in 2021 compared to 2020. These factors are projected to impede the global market throughout the forecast period.

Impact of Covid-19 on the Uranium Mining Market

The pandemic caused a slowdown in economic activity, lowering demand for electricity and, thus, nuclear power. This decrease in demand for nuclear energy resulted in lower demand for uranium. The epidemic disrupted supply lines, making it impossible for ...

Nuclear Energy Index fell to 44.45 USD on December 1, 2025, down 2.65% from the previous day. Over the past month, Nuclear Energy Index's price has fallen 14.94%, but it is still 37.74% higher than a year ago, according to trading on a contract for difference (CFD) that tracks the benchmark market for this commodity. This dataset includes a chart with historical data for Nuclear Energy Index.

Index Time Series for Global X Uranium Index ETF. The frequency of the observation is daily. Moving average series are also typically included. NA

United States - Producer Price Index by Industry: Other Metal Ore Mining: Other Metal Ores, Including Uranium was 2094.53800 Index Dec 2003=100 in July of 2023, according to the United States Federal Reserve. Historically, United States - Producer Price Index by Industry: Other Metal Ore Mining: Other Metal Ores, Including Uranium reached a record high of 2762.31300 in May of 2022 and a record low of 100.00000 in December of 2003. Trading Economics provides the current actual value, an historical data chart and related indicators for United States - Producer Price Index by Industry: Other Metal Ore Mining: Other Metal Ores, Including Uranium - last updated from the United States Federal Reserve on November of 2025.

Studies of marine terraces and their fossils can yield important information about sea level history, tectonic uplift rates, and paleozoogeography. The marine terrace record on Santa Rosa Island, California is complex. Two prominent low-elevation terraces appear to record the ~80 ka (MIS 5a) and ~120 ka (MIS 5e) high-sea stands, based on U-series dating of fossil corals, but interpretations are tentative because of clear indications of open-system behavior with respect to U-series nuclides. Nevertheless, low uplift rates are implied by a preferred interpretation of the ages. It is inferred that low late Pleistocene uplift rates, combined with glacial isostatic adjustment (GIA) processes likely resulted in reoccupation of the ~120 ka 2nd terrace during the ~100 ka (MIS 5c) high-sea stand. Study of a high-elevation marine terrace on the western part of Santa Rosa Island also shows evidence of fossil mixing. Strontium isotope ages of fossil mollusks indicate an age range of ~500 ka at one locality and ~600 ka at another locality. Consideration of elevations and ages here also yield low, long-term uplift rates, which explains, at least in part, the potential for terrace reoccupation in the early Pleistocene. In addition, however, early Pleistocene glacial-interglacial cycles were of much shorter duration, linked to the ~41 ka obliquity cycle of orbital forcing, a factor that would also enhance terrace reoccupation in regions of low uplift rate.

The Middle East and Africa Uranium Mining market was USD 170.96 million in 2024 and will grow at a compound annual growth rate (CAGR) of 4.2% from 2024 to 2031. The market is foreseen to reach USD 244.3 million by 2031, owing to increasing global demand for nuclear energy.

Index Time Series for Sprott Junior Uranium Miners ETF. The frequency of the observation is daily. Moving average series are also typically included. The fund will, under normal circumstances, invest at least 80% of its total assets in securities of the index. The index is designed to track the performance of companies that derive at least 50% of their revenue and/or assets from (i) mining, exploration, development, and production of uranium; (ii) earning uranium royalties; and/or (iii) supplying uranium. The index generally consists of from 30 to 40 constituents. The fund is non-diversified.

Latin America's Uranium Mining market was USD 427.41 million in 2024 and is estimated to grow at a compound annual growth rate (CAGR) of 3.9% from 2024 to 2031. The market is foreseen to reach USD 616.5 million by 2031 due to investment in the uranium mining industry.

High-resolution records of the natural radionuclide 230Th were measured in sediments from the eastern Atlantic sector of the Antarctic circumpolar current to obtain a detailed reconstruction of the sedimentation history of this key area for global climate change during the late Quaternary. High-resolution dating rests on the assumption that the 230Thex flux to the sediments is constant. Short periods of drastically increased sediment accumulation rates (up to a factor of 8) were determined in the sediments of the Antarctic zone during the climate optima at the beginning of the Holocene and the isotope stage 5e. By comparing expected and measured accumulation rate of 230Thex, lateral sediment redistribution was quantified and vertical particle rain rates originating from the surface water above were calculated. We show that lateral contributions locally were up to 6.5 times higher than the vertical particle rain rates. At other locations only 15% of the expected vertical particle rain rate were deposited.

A down-core 231Pa/230Th record has been measured from the southwestern Indian Ocean to reconstruct the history of deep water flow into this basin over the last glacial-interglacial cycle. The (231Paxs/230Thxs)0 ratio throughout the record is nearly constant at approximately 0.055, significantly lower than the production ratio of 0.093, indicating that the proxy is sensitive to changes in circulation and/or sediment flux at this site. The consistent value suggests that there has been no change in the inflow of Antarctic Bottom Water to the Indian Ocean during the last 140 ka, in contrast to the changes in deep circulation thought to occur in other ocean basins. The stability of the (231Paxs/230Thxs)0 value in the record contrasts with an existing sortable silt (SS) record from the same core. The observed equation image variability is attributed to a local geostrophic effect amplifying small changes in circulation. A record of authigenic U from the same core suggests that there was reduced oxygen in bottom waters at the core locality during glacial periods. The consistency of the (231Paxs/230Thxs)0 record implies that this could not have arisen by local changes in productivity, thus suggesting a far-field control: either globally reduced bottom water oxygenation or increased productivity south of the Opal Belt during glacials.