Lithium rose to 82,000 CNY/T on August 14, 2025, up 1.23% from the previous day. Over the past month, Lithium's price has risen 26.35%, and is up 10.07% compared to the same time last year, according to trading on a contract for difference (CFD) that tracks the benchmark market for this commodity. Lithium - values, historical data, forecasts and news - updated on August of 2025.

This data release provides the descriptions of approximately 20 U.S. sites that include mineral regions, mines, and mineral occurrences (deposits and prospects) that contain enrichments of lithium (Li). This release includes sites that have a contained resource and (or) past production of lithium metal greater than 15,000 metric tons. Sites in this database occur in Arkansas, California, Nevada, North Carolina, and Utah. There are several deposits that were not included in the database because they did not meet the cutoff requirement, and those occur in Arizona, Colorado, the New England area, New Mexico, South Dakota, and Wyoming. In the United States, lithium was first mined from pegmatite orebodies in South Dakota in the late 1800s. The Kings Mountain pegmatite belt of North Carolina also had significant production from pegmatites, and the area may still contain as much as 750 million metric tons (Mt) of ore containing 5 Mt lithium metal (Kesler and others, 2012). In 2018, U.S. production of lithium was restricted to a single lithium-brine mining operation in Nevada. In 2018, the U.S. had a net import reliance as a percentage of apparent consumption of more than 50 percent for lithium (U.S. Geological Survey, 2019). The U.S. is not a significant producer of lithium, so the commodity is mainly imported from Chile and Argentina to meet consumer demand. Lithium is necessary for strategic, consumer, and commercial applications. The primary uses for lithium are in batteries, ceramics, glass, metallurgy, pharmaceuticals, and polymers (U.S. Geological Survey, 2019). Lithium has excellent electrical conductivity and low density (lithium metal will float on water), making it an ideal component for battery manufacturing. Lithium is traded in three primary forms: mineral concentrates, mineral compounds (from brines), and refined metal (electrolysis from lithium chloride). Lithium mineralogy is diverse; it occurs in a variety of pegmatite minerals such as spodumene, lepidolite, amblygonite, and in the clay mineral hectorite. Current global production of lithium is dominated by pegmatite and closed-basin brine deposits, but there are significant resources in lithium-bearing clay minerals, oilfield brines, and geothermal brines (Bradley and others, 2017). The entries and descriptions in the database were derived from published papers, reports, data, and internet documents representing a variety of sources, including geologic and exploration studies described in State, Federal, and industry reports. Resources extracted from older sources might not be compliant with current rules and guidelines in minerals industry standards such as National Instrument 43-101 (NI 43-101) or the Joint Ore Reserves Committee Code (JORC Code). The inclusion of a particular lithium mineral deposit in this database is not meant to imply that the deposit is currently economic. Rather, these deposits were included to capture the characteristics of the larger lithium deposits in the United States, which are diverse in their geology and resource potential. Inclusion of material in the database is for descriptive purposes only and does not imply endorsement by the U.S. Government. The authors welcome additional published information in order to continually update and refine this dataset. Bradley, D.C., Stillings, L.L., Jaskula, B.W., Munk, LeeAnn, and McCauley, A.D., 2017, Lithium, chap. K of Schulz, K.J., DeYoung, J.H., Jr., Seal, R.R., II, and Bradley, D.C., eds., Critical mineral resources of the United States—Economic and environmental geology and prospects for future supply: U.S. Geological Survey Professional Paper 1802, p. K1–K21, https://doi.org/10.3133/pp1802K. Kesler, S.E., Gruber, P.W., Medina, P.A., Keoleian, G.A., Everson, M.P., and Wallington, T.J., 2012, Global lithium resources—relative importance of pegmatite, brine and other deposits: Ore Geology Reviews, v. 48, October ed., p. 55—69. U.S. Geological Survey, 2019, Mineral commodity summaries 2019: U.S. Geological Survey, 200 p., https://doi.org/10.3133/70202434.

Batteries have the potential to significantly reduce greenhouse gas emissions from on-road transportation. However, environmental and social impacts of producing lithium-ion batteries, particularly cathode materials, and concerns over material criticality are frequently highlighted as barriers to widespread electric vehicle adoption. Circular economy strategies, like reuse and recycling, can reduce impacts and secure regional supplies. To understand the potential for circularity, we undertake a dynamic global material flow analysis of pack-level materials that includes scenario analysis for changing battery cathode chemistries and electric vehicle demand. Results are produced regionwise and through the year 2040 to estimate the potential global and regional circularity of lithium, cobalt, nickel, manganese, iron, aluminum, copper, and graphite, although the analysis is focused on the cathode materials. Under idealized conditions, retired batteries could supply 60% of cobalt, 53% of lith...

As of 2024, the world's total lithium resources were estimated at some 115 million metric tons of lithium content. Bolivia and Argentina boasted the largest resources at the time, with some 23 million metric tons each. The United States ranked third that year, at about 19 million metric tons of lithium content.

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.

S. Quimica Sees Lithium Demand Boosting (SQM) Stock's Future.

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

Lithium-ion battery (LIB) recycling technologies are advancing rapidly, with higher recovery efficiencies, lower energy demand, and more complex supply chains. Previous life cycle assessment (LCA) studies overlook evolving industry recycling practices and often disregard key impact categories, such as water consumption, toxicity, and resource depletion potential. Previous studies also do not evaluate battery recycling methods within the current supply chain context, specifically accounting for prevailing battery waste composition, final cathode material outputs, and varying geographic locations of recycling stages. This study compares conventional hydrometallurgy (CHR), truncated hydrometallurgy (THR), and pyrometallurgy (PR) recycling in North America, Europe, and China. This work considers each method’s recycling efficiency and the additional primary materials required to produce the new NMC811 CAM. Leaching and materials extraction contribute the most to the environmental footprint of recycling. Skipping metals’ extraction in THR leads to the lowest carbon footprint, water consumption, and toxicity. Compared to China, recycling and manufacturing in North America reduce the carbon footprint and freshwater toxicity of the NMC811 CAM by 16% and 30%, respectively. Careful selection of the recycling and production locations can reduce the environmental impact of a modern EV NMC811 battery pack by 792 kg CO2-eq and 11,355 L of water, respectively.

The ternary lithium-ion battery market is experiencing robust growth, driven by increasing demand from the electric vehicle (EV) sector and the burgeoning energy storage systems (ESS) market. The market's Compound Annual Growth Rate (CAGR) is projected to be significant throughout the forecast period (2025-2033), fueled by government initiatives promoting electric mobility and renewable energy integration, coupled with advancements in battery technology leading to improved energy density, lifespan, and safety. Key application segments like automotive and consumer electronics are major contributors to market expansion. Within the automotive sector, the shift towards electric and hybrid vehicles is a primary driver, while in consumer electronics, the demand for high-performance batteries in portable devices and power tools is steadily rising. The NCM (Nickel Manganese Cobalt) type currently dominates the market due to its superior energy density, but the NCA (Nickel Cobalt Aluminum) type is witnessing growing adoption due to its potential for higher energy density and improved performance at higher temperatures. However, the market faces challenges including fluctuating raw material prices, particularly cobalt, and concerns regarding battery safety and sustainability. Geographical analysis reveals strong growth potential in the Asia-Pacific region, particularly in China, driven by a large and rapidly growing EV market, alongside significant expansion in North America and Europe as governments implement supportive policies and consumer demand intensifies. Competition in the market is intense, with established players such as Panasonic and BYD vying with emerging companies for market share. Future growth will depend on continuous innovation in battery technology, addressing the challenges of raw material sourcing, enhancing safety protocols, and developing sustainable recycling solutions. The overall market size in 2025 is estimated at $50 billion, considering the current growth trajectory and the projected CAGR of 15%. This is based on reasonable estimations derived from publicly available data on related battery markets and industry reports, but is not derived from a specific data set provided. This will increase steadily until 2033. The industrial segment will present a significant opportunity due to its increasing demand for energy storage. Ongoing research and development efforts focused on improved battery chemistry, higher energy densities, and reduced costs promise to further drive market expansion in the coming years. Strategies like establishing strong supply chains and strategic partnerships will play a crucial role for companies aiming to thrive in this dynamic and competitive landscape.

Uncover the global Lithium Hexafluorophosphate (LiPF6) market's future! Our study explores key trends, forecasts, and insightful analysis. Dive in and discover lucrative opportunities in this dynamic market.

Energy storage technology as a key support technology for China’s new energy development, the demand for critical metal minerals such as lithium, cobalt, and nickel is growing rapidly. However, these minerals have high external dependence and concentrated import sources, increasing the supply risk caused by geopolitics. It is necessary to evaluate the supply risks of critical metal minerals caused by geopolitics to provide a basis for the high-quality development of energy storage technology in China. Based on geopolitical data of eight countries from 2012 to 2020, the evaluation indicators such as geopolitical stability, supply concentration, bilateral institutional relationship, and country risk index were selected to analyze the supply risk of three critical metal minerals, and TOPSIS was applied to construct an evaluation model for the supply risk of critical metal minerals of lithium, cobalt, and nickel in China. The results show that from 2012 to 2017, the security index of cobalt and lithium resources is between .6 and .8, which is in a relatively safe state, while the security index of nickel resources is .2–.4, which is in an unsafe state. From 2017 to 2020, lithium resources remain relatively safe, and the security index of nickel has also risen to between .6 and .7, which is generally in a relatively safe state. However, the security index of cobalt has dropped to .2, which is in an unsafe or extremely unsafe state. Therefore, China needs to pay attention to the safe supply of cobalt resources and formulate relevant strategies to support the large-scale development of energy storage technology.

During the second quarter of 2024, the ethylene carbonate (EC) prices in China reached 878 USD/MT in June, due to the increasing product utilization by manufacturers of lithium-ion battery and disruptions in supply. Prices rose 13% from the previous year and 2% from the last quarter, reflecting steady consumption and ongoing supply constraints.