Uranium decreased 8.70 USD/LBS or 11.92% since the beginning of 2025, 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 March of 2025.

In December 2024, the global average price per pound of uranium stood at roughly 60.22 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 2023 was 48.99 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.

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

The average annual price for one pound of uranium was 48.99 U.S. dollars in 2023. This is the highest annual average since 2011, 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.

This analysis presents a rigorous exploration of financial data, incorporating a diverse range of statistical features. By providing a robust foundation, it facilitates advanced research and innovative modeling techniques within the field of finance.

Uranium Energy (YCA): The Sun's Yellow Cake, or Just a Fool's Gold Investment?

Financial data:

• Historical daily stock prices (open, high, low, close, volume)

• Fundamental data (e.g., market capitalization, price to earnings P/E ratio, dividend yield, earnings per share EPS, price to earnings growth, debt-to-equity ratio, price-to-book ratio, current ratio, free cash flow, projected earnings growth, return on equity, dividend payout ratio, price to sales ratio, credit rating)

• Technical indicators (e.g., moving averages, RSI, MACD, average directional index, aroon oscillator, stochastic oscillator, on-balance volume, accumulation/distribution A/D line, parabolic SAR indicator, bollinger bands indicators, fibonacci, williams percent range, commodity channel index)

Machine learning features:

• Feature engineering based on financial data and technical indicators

• Sentiment analysis data from social media and news articles

• Macroeconomic data (e.g., GDP, unemployment rate, interest rates, consumer spending, building permits, consumer confidence, inflation, producer price index, money supply, home sales, retail sales, bond yields)

Potential Applications:

• Stock price prediction

• Portfolio optimization

• Algorithmic trading

• Market sentiment analysis

• Risk management

Use Cases:

• Researchers investigating the effectiveness of machine learning in stock market prediction

• Analysts developing quantitative trading Buy/Sell strategies

• Individuals interested in building their own stock market prediction models

• Students learning about machine learning and financial applications

Additional Notes:

• The dataset may include different levels of granularity (e.g., daily, hourly)

• Data cleaning and preprocessing are essential before model training

• Regular updates are recommended to maintain the accuracy and relevance of the data

Global demand for uranium was forecasted to reach 240 million pounds of U3O8 by 2035. While demand will be growing constantly, supply of uranium was expected to drop over time. It was forecasted that new assets will be required to fill that supply gap.

3639 Global import shipment records of Uranium with prices, volume & current Buyer's suppliers relationships based on actual Global export trade database.

The global enriched uranium material market is poised for substantial growth, projected to reach a market size of $15 billion by 2025, with a Compound Annual Growth Rate (CAGR) of 5% from 2025 to 2033. This expansion is driven primarily by the increasing global demand for nuclear energy to meet rising electricity needs and the sustained military applications of enriched uranium. Several key trends are shaping this market, including advancements in enrichment technologies leading to greater efficiency and reduced costs, growing investments in nuclear power plant infrastructure globally, particularly in Asia and the Middle East, and a renewed focus on nuclear energy as a low-carbon alternative. However, the market faces certain restraints, including stringent regulations and safety concerns surrounding nuclear materials, fluctuations in uranium prices impacting production costs, and the ongoing debate surrounding nuclear waste disposal. The market is segmented by enrichment level (low and high enriched uranium) and application (military, nuclear power plants, and other uses). Major players such as Areva, Urenco, Tenex, CNNC, and Orano are competing in a market characterized by significant regional variations in demand. North America and Europe currently hold the largest market share, but Asia-Pacific is expected to witness significant growth in the coming years due to increasing investments in nuclear power generation. The consistent demand from nuclear power plants, coupled with the steady military application of enriched uranium, signifies strong long-term market stability. While challenges like regulatory hurdles and price volatility persist, technological advancements and the global push toward cleaner energy sources are expected to mitigate these factors, contributing to the market's sustained growth trajectory. The ongoing development of advanced reactor designs and associated fuel requirements will further influence market dynamics throughout the forecast period, creating opportunities for companies with innovative technologies and efficient production processes. Strategic partnerships and collaborations amongst industry players will play a vital role in navigating the complexities of this specialized market and capitalizing on emerging opportunities.

Nuclear Energy Index decreased 2.51 USD or 9.38% since the beginning of 2025, 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.

Uranium exploration expenditure in Australia has increased progressively since 2003 mainly because of the significant increases in spot market uranium prices in recent years. In 2007-08, uranium exploration expenditure increased to a record level of $231.6 million , which is approximately double the 2006-07 expenditure ($111.4 million). The majority of expenditure was in South Australia (51%), followed by the Northern Territory (21%), Queensland (16%) and Western Australia (12%). Uranium exploration expenditure in the 2008 September quarter ($56.7 million) was above the 2007 September quarter ($50 million). However the difference is the expenditure trend from the June quarter to the September quarter, in 2007 expenditure grew by $6.7 million whereas in 2008 expenditure reduced by $6.0 million. This reduction may reflect that the current global economic crisis is affecting the level of uranium exploration spending. Geoscience Australia prepares annual estimates of Australia's uranium resources within categories used for international reporting by the Uranium Group (a joint initiative of the OECD Nuclear Energy Agency and the International Atomic Energy Agency). The estimates are for resources of recoverable uranium after losses due to mining and milling have been deducted.
As of December 2008, Australia's Reasonably Assured Resources (RAR) recoverable at costs of

19296 Global exporters importers export import shipment records of Uranium with prices, volume & current Buyer's suppliers relationships based on actual Global export trade database.

Colombia GDP: sa: Mining and Quarrying: Crude Oil, Natural Gas and Uranium Minerals data was reported at 4,299,301.000 COP mn in Dec 2007. This records an increase from the previous number of 2,837,051.000 COP mn for Sep 2007. Colombia GDP: sa: Mining and Quarrying: Crude Oil, Natural Gas and Uranium Minerals data is updated quarterly, averaging 1,643,443.000 COP mn from Mar 1994 (Median) to Dec 2007, with 56 observations. The data reached an all-time high of 4,299,301.000 COP mn in Dec 2007 and a record low of 231,044.000 COP mn in Mar 1994. Colombia GDP: sa: Mining and Quarrying: Crude Oil, Natural Gas and Uranium Minerals data remains active status in CEIC and is reported by National Administrative Department of Statistics. The data is categorized under Global Database’s Colombia – Table CO.A047: SNA 1993: GDP: by Industry: Current Price: Base 1994: Seasonally Adjusted.

Nuclear electricity generated in the United States cost 30.92 U.S. dollars per megawatt-hour in 2022. Production costs were highest in 2012, when they came to 51.22 U.S. dollars in 2022 prices, but have decreased ever since. Some 775 terawatt-hours of electricity is generated by U.S. nuclear plants every year. Capacity factor of nuclear power Among all the U.S. energy sources, nuclear power has by far the highest capacity factor and is dependable and efficient. In 2023, nuclear power reactors generated more than 93% of the electrical energy that could have been produced at continuous full power operation in 2023. Outage patterns and maintenance of nuclear plants Despite having a high capacity factor, nuclear plants experienced peak average daily outages of nearly 22 gigawatts in April and October of the last few years. These outages, planned for low-demand periods, reflect necessary refueling and maintenance. As of October 2023, the average duration of these refueling outages was 35 days, illustrating the balance between high operational efficiency and periodic maintenance required to sustain reliable performance.

Here we present records of International Ocean Discovery Program (IODP) Site U1460 (eastern Indian Ocean, 27°22.49′S, 112°55.42′E), including surface water productivity (alkenone abundances, total nannofossil as well as alkenone producing nannofossil abundances and accumulation rates), as well as relative abundances of small Gephyrocapsa spp. and Reticulofenestra asanoi, which were used in age model generation. Furthermore, we provide organic matter flux (total organic carbon and Uranium content and mass accumulation rates), as well as biogenic silica and terrigenous flux records in combination with bulk calcite equivalent calcium carbonate content. Absolute and relative Nannofossil data was generated using the drop technique (c.f. Bordiga et al., 2015, doi: 10.1016/j.revmic.2015.05.002), with mass accumulation rates calculated based on the attached age model. Bulk total and organic carbon content measured in a LECO CS300 carbonate and sulfur analyzer and calculated mass accumulation rates of organic carbon and the calcite equivalent carbonate content. Alkenone abundances and calculated accumulation rates are derived from data originally measured for Petrick et al. (2019, doi: 10.1038/s41598-019-53382-0). Shipboard whole round multi-senor logger natural gamma radiation derived U content (see De Vleeschouwer et al., 2017, doi:10.1002/2016gc0067159) and calculated U mass accumulation rates. X-ray fluorescence (XRF) derived element counts originally published in Petrick et al. (2019, doi: 10.1038/s41598-019-53382-0) are used to calculate log normalized multi-element ratios ln((Al+K)/Ca) and ln(Si/(Al+Ca)). The gathered proxy data covers the interval between 61 and 163 m CSF-A, corresponding to an age of 1.1 – 0.6 Ma, based on the attached age model. The data records Pleistocene Leeuwin Current dynamics and sea level-driven environmental changes along the West Australian shelf over the MPT.

The global market for Zirconium Alloy Nuclear Fuel Cladding Tubes is experiencing steady growth, driven by the increasing demand for nuclear energy as a reliable and low-carbon energy source. The market, estimated at $2.5 billion in 2025, is projected to exhibit a Compound Annual Growth Rate (CAGR) of approximately 5% from 2025 to 2033, reaching an estimated value of $3.8 billion by 2033. This growth is fueled by several factors, including the ongoing construction and operation of new nuclear power plants worldwide, particularly in countries focusing on energy security and decarbonization. Furthermore, the development of advanced reactor designs and the extension of the operational lifespan of existing reactors are contributing to the increased demand for replacement and additional cladding tubes. The market is segmented by reactor type (BWR, PWR, HWR, and others) and tube diameter (0.25-0.5 inch and 0.5-1.0 inch), with PWRs currently dominating the market share due to their wider adoption. Key players in this space include Global Nuclear Fuel-Americas (GNF), Sandvik Materials, and Westinghouse Specialty Metals Plant (SMP), amongst others, constantly innovating to improve cladding tube performance, reliability, and efficiency. Competitive pressures and technological advancements are shaping the market landscape. Geographical distribution shows a concentration of demand in regions with established nuclear power infrastructure, including North America, Europe, and Asia-Pacific. However, emerging markets in developing economies are anticipated to witness significant growth in the coming years, driven by increasing energy demands and government initiatives to expand nuclear power capacity. While the market faces restraints like fluctuating uranium prices and stringent regulatory requirements, the long-term outlook for Zirconium Alloy Nuclear Fuel Cladding Tubes remains positive, spurred by the global focus on sustainable energy solutions and the inherent safety and reliability of nuclear power. Specific regional growth rates will vary depending on the pace of nuclear plant construction and government policies within each region. The competitive landscape is characterized by both established players and newer entrants, leading to a dynamic market environment with ongoing advancements in material science and manufacturing processes.