Nickel fell to 14,879.88 USD/T on December 3, 2025, down 0.20% from the previous day. Over the past month, Nickel's price has fallen 1.20%, and is down 7.47% compared to the same time last year, according to trading on a contract for difference (CFD) that tracks the benchmark market for this commodity. Nickel - values, historical data, forecasts and news - updated on December of 2025.

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

In recent years, nickel prices have hit some of their all-time highest numbers, at an average of almost 26,000 U.S. dollars per metric ton throughout 2022. This was driven by a large spike in prices at the end of that year, where they peaked at 31,275 U.S. dollars per ton in mid-November. The recent surge in nickel prices has been driven by several factors, including disruptions to Russia's (the world's third-largest nickel producer) export industry following its invasion of Ukraine. Additionally, demand for nickel has grown alongside the growth of lithium-ion battery production, driven by the growth of the electronic car market. However, these recent peaks are still well below the all-time annual high of more than 37,000 U.S. dollars in 2007, where low international supply coupled with high demand from China's stainless-steel manufacturing industries caused prices to soar.

In May 2024, the price of one metric ton of nickel stood at some ********* U.S. dollars. In comparison, in December 2016, the price of nickel was just below ****** U.S. dollars per metric ton. Thus, the nickel price has increased considerably in recent years, though it continuously fluctuates. In the beginning of 2022, however, the price of nickel skyrocketed due to disruptions to supply chains and a wide scarcity of raw materials and metals. Overview of nickel Discovered in 1751, nickel is a base metal with a silvery-white lustrous appearance that has a slightly golden tinge. The metal is crucial for many global industries, especially, for example, for the production of stainless-steel. Nickel is highly corrosion-resistant and is used to plate other metals in order to protect them. Because of these useful traits, nickel is used in more than ******* products worldwide, spanning from architectural, industrial, military, transportation and aerospace, marine, currency, and consumer applications. Nickel price dynamics Though nickel is the fifth most abundant element found on Earth, as with any commodity, the price of nickel can vary widely depending on global market conditions. Following the collapse of the Soviet Union, exports of nickel increased dramatically, dropping the price of nickel in the mid-1990s to below production costs. Nickel production in the Western Hemisphere was reduced during that period. Prices then increased again, up to a high of ****** U.S. dollars per metric ton in May 2007. Since then, nickel prices have decreased, and have remained between a low of ***** U.S. dollars per metric ton and a high of ****** U.S. dollars per metric ton between 2016 and 2021. It is forecast that the price of nickel will amount to more than ****** U.S. dollars per metric ton in 2025.

Explore the factors influencing the spot price of nickel, a vital industrial metal crucial for stainless steel and electric vehicle batteries. Learn about the impact of supply dynamics, technological innovations, global stockpiles, and environmental considerations in shaping nickel's market value.

Current spot price plus 1-month and 1-year forecasts for Nickel as published on ChAI Predict.

In situ synchrotron x-ray radiography; Single spot melting and solidification; Pure nickel; Beamline 32-ID, APS Link to the radiography data provided in: "In-situ Measurement Details" (Access Restricted)

This dataset presents metal concentrations in transitional and coastal waters measured in Diffusive Gradients in Thin-films (DGT) passive samplers by Inductively Coupled Plasma Mass Spectrometry (ICP-MS: Cd, Co, Cu, Fe, Mn, Ni, Pb, Zn) and in concurrently collected spot samples by ICP-MS (Al, Cd, Co, Cu, Mn, Ni, Pb, Zn) and Anodic/Cathodic Stripping Voltammetry (ASV/CSV: Cd, Ni, Pb) and obtained in the framework of the MONITOOL Project. Data on seawater physico-chemical parameters is also provided (salinity, temperature, dissolved oxygen, pH, turbidity, total suspended solids, dissolved organic carbon, total organic carbon). Sampling sites include the following ecoregions: Canary Islands, Iberian Coast, Bay of Biscay and English Channel, Celtic Sea North Sea and Western Mediterranean Sea (for detailed description of sampling sites see Caetano et al., Marine Pollution Bulletin 179 (2022) 113715). ICP-MS and voltammetry analysis (Anodic Stripping Coltammetry: Cd and Pb; Cathodic Stripping Voltammetry: Ni) were carried out in filtered seawater (see Bersuder et al., MethodsX 8 (2021) 101462; Rodríguez et al., Science of the Total Environment 783 (2021) 147001; Amouroux et al., Environmental Sciences Europe (2023) 35:29). Detailed description of the DGT technique and a user-friendly guidance can be found in Millán et al. (2021. A Good Practice Guide for the Use of DGTs. ITC. ISBN: 978-84-09-30846-0) and Gonzalez et al. (Science of the Total Environment 847 (2022) 157499). More info: https://www.monitoolproject.eu.

Yearly citation counts for the publication titled "Parametric Effects of Resistance Spot Welding between Li-ion Cylindrical Battery Cell and Nickel Conductor Strip".

Battery Metals Spot Trading Platform Market Outlook

According to our latest research, the Battery Metals Spot Trading Platform market size reached USD 1.28 billion in 2024, reflecting the rapid digitization of commodity trading and surging demand for battery metals across the globe. The market is expected to expand at a robust CAGR of 23.7% from 2025 to 2033, reaching a forecasted value of USD 10.14 billion by 2033. This remarkable growth is primarily driven by the exponential rise in electric vehicle (EV) production, the proliferation of renewable energy storage solutions, and increasing transparency and efficiency needs in the metals supply chain.

A key growth factor for the Battery Metals Spot Trading Platform market is the unprecedented surge in global EV adoption, which is fueling demand for critical battery metals such as lithium, cobalt, nickel, and manganese. As automotive OEMs ramp up their electrification strategies, the need for reliable, real-time pricing and transaction platforms for these metals has become paramount. Spot trading platforms are bridging the gap between miners, refiners, manufacturers, and end-users, enabling instant price discovery and efficient execution of trades. Additionally, the shift towards localized and sustainable supply chains, especially in response to geopolitical uncertainties and supply disruptions, is further accelerating the adoption of digital spot trading platforms for battery metals.

Another significant driver is the increasing penetration of renewable energy storage systems, which rely heavily on advanced battery chemistries. Utility-scale and distributed energy storage projects are propelling demand for metals like lithium and nickel, making efficient and transparent spot trading platforms indispensable for energy companies, battery manufacturers, and investors. The integration of blockchain and AI technologies into these platforms enhances transaction security, traceability, and market analytics, attracting a wider range of participants and fostering greater market liquidity. Moreover, the growing focus on sustainability and responsible sourcing is prompting stakeholders to leverage digital platforms for verifying the provenance and environmental footprint of traded metals.

Furthermore, regulatory support and industry initiatives aimed at standardizing battery metals trading are catalyzing market growth. Governments and industry bodies in major regions are introducing frameworks to ensure fair pricing, reduce counterparty risk, and promote supply chain transparency. This regulatory push is encouraging traditional commodity traders and new entrants alike to adopt spot trading platforms, which offer compliance-ready solutions and auditable transaction records. The evolving landscape of battery recycling and secondary metals markets is also creating new opportunities for spot trading platforms, as the circular economy gains traction in the battery value chain.

From a regional perspective, Asia Pacific dominates the Battery Metals Spot Trading Platform market, accounting for over 47% of global revenue in 2024, driven by China’s leadership in battery manufacturing, mineral processing, and EV adoption. North America and Europe are also witnessing robust growth, fueled by ambitious decarbonization targets, investments in battery gigafactories, and a strong focus on supply chain resilience. The Middle East & Africa and Latin America are emerging as strategic sources of battery metals and are increasingly leveraging spot trading platforms to connect with global buyers, enhance market access, and maximize resource value.

Metal Type Analysis

The Metal Type segment is a cornerstone of the Battery Metals Spot Trading Platform market, encompassing key metals such as lithium, cobalt, nickel, manganese, and others. Lithium remains the most traded metal on these platforms, accounting for over 38% of spot trading volume in 2024. The meteoric rise in lithium demand is

Herein, a full spectrum-induced hybrid structure consisting of one-dimensional nickel titanate (NiTiO3) nanofibers (NFs) decorated by petal-like molybdenum disulfide (MoS2) particles was designed through a facile hydrothermal method. The key parameters for tailoring the morphology and chemical, surface, and interfacial properties of the heterostructure were identified for efficient and selective conversion of CO2 into valuable chemicals. Introducing MoS2 layers onto NiTiO3 NFs provided superior CO2 conversion with significantly higher yields. The optimized hybrid structure produced CO and CH4 yields of 130 and 55 μmol g−1 h−1, respectively, which are 3.8- and 3.6-times higher than those from pristine NiTiO3 nanofibers (34 and 15 μmol g−1 h−1, respectively) and 3.6- and 5.5-times higher than those from pristine MoS2 (37 and 10 μmol g−1 h−1, respectively). This improved performance was attributed to efficient absorption of a wider spectrum of light and efficient transfer of electrons across the heterojunction. Effective charge separation and reduced charge carrier recombination were confirmed by photoluminescence and impedance measurements. The performance may also be partly due to enhanced hydrophobicity of the hierarchical surfaces due to MoS2 growth. This strategy contributes to the rational design of perovskite-based photocatalysts for CO2 reduction.

Macroporous catalysts exhibit excellent mass and heat transfer properties, thereby reducing pressure drop and mitigating hot spot formation during the reaction process. Addressing the issue of sintering of the active component on the catalyst due to the strong exothermicity of CO2 methanation and the demand for reactions to operate at high space velocities, this study for the first time utilized macroporous Al2O3 for CO2 methanation reactions. A catalyst comprising a high surface area, large pore size, and high pore volume was prepared by in-situ growth of layered double hydroxide (LDH) precursors on the surface of macroporous Al2O3. The effects of calcination temperature, reduction temperature, and space velocity on the catalyst structure and reaction performance were studied. The phase composition of the catalyst is controlled by adjusting the calcination temperature, the reduction degree of Ni is regulated and the sintering of Ni is avoided by controlling the reduction temperature , and the number of active sites of Ni0 in the reduced catalyst is increased, thus the activity of the catalyst is improved. The results demonstrate that after calcination of the NiMgAl-LDH precursor at 400 oC and reduction at 650 oC, the resulted Ni-MgO/Al2O3 showed the highest Ni activity-specific surface area, which is the best catalyst with highest CO2 conversion and CH4 selectivity, indicating that increasing the surface area of metal nickel is crucial for the catalytic performance. Furthermore, the material maintained high catalytic performance at WHSV = 80000 mL g-1 h-1, indicating its suitability for high space velocity operations. Additionally, at a test temperature of 550 oC, the catalyst exhibited excellent stability, with CO2 conversion and CH4 selectivity respectively remaining at 54% and 79%.

The following data files include microstructure measurement results associated with the 2022 Additive Manufacturing Benchmark test series (AM Bench 2022) AMB2022-03 set of benchmarks. These AMB2022-03 benchmarks explore a range of individual and overlapping melt pool behaviors using individual laser tracks and 2D arrays of laser tracks (pads) on solid metal IN718 plates. For the individual laser tracks, a range of laser parameters was used, with variations in laser power, speed, and spot diameter. For the laser pads, the laser scan patterns and most of the laser parameters match those used for the 2.5 mm legs from the AMB2022-01 3D builds. The laser tracks and pads were cross sectioned at different locations and examined using scanning electron microscopy (SEM) electron backscatter diffraction (EBSD) and energy dispersive spectroscopy (EDS). Descriptions and measurement data for all of the other AMB2022-03 measurements may be found on the AM Bench website at www.nist.gov/ambench.The AM Bench measurements metadata catalog provides both a web search interface and API access to extensive linked data associated with these measurements (see Data Access link to explore this related resource). The SciServer AM Bench collaborative compute platform provides a mechanism for exploring and analyzing the AM Bench datasets directly on a data server without the need to download large datasets (see Data Access link to explore this related resource).

Molybdenum traded flat at 455.50 CNY/Kg on November 28, 2025. Over the past month, Molybdenum's price has fallen 8.99%, and is down 4.11% compared to the same time last year, according to trading on a contract for difference (CFD) that tracks the benchmark market for this commodity. Molybdenum - values, historical data, forecasts and news - updated on December of 2025.

Battery Metals Refining Market Outlook

According to our latest research, the global battery metals refining market size reached USD 21.6 billion in 2024, and is expected to expand at a robust CAGR of 9.4% during the forecast period, reaching approximately USD 48.7 billion by 2033. This impressive growth trajectory is primarily driven by the surging demand for electric vehicles (EVs), rapid advancements in battery technologies, and increasing adoption of renewable energy storage solutions worldwide. The marketÂ’s expansion is further propelled by the global push towards decarbonization and the critical need for high-purity battery metals to ensure the performance and safety of next-generation batteries.

One of the key growth factors in the battery metals refining market is the exponential rise in electric vehicle adoption. Governments across major economies are implementing stringent emission regulations, offering incentives for EV purchases, and setting ambitious targets for phasing out internal combustion engine vehicles. This has created a massive surge in demand for refined lithium, cobalt, nickel, and manganese, which are essential for manufacturing high-performance lithium-ion batteries. Additionally, the ongoing innovation in battery chemistries, such as the development of solid-state and high-nickel cathode batteries, is increasing the need for ultra-high-purity metals, thereby driving investments in advanced refining processes and technologies.

Another significant driver is the expansion of renewable energy infrastructure, particularly the deployment of grid-scale energy storage systems. As nations strive to integrate more solar and wind power into their energy mix, the demand for robust and efficient energy storage solutions is escalating. This, in turn, is fueling the requirement for refined battery metals, as these materials are pivotal for manufacturing large-format batteries used in energy storage systems. Furthermore, the proliferation of portable consumer electronics, such as smartphones, laptops, and wearable devices, continues to support steady growth in the battery metals refining market, as these products require reliable and long-lasting battery solutions.

Technological advancements in refining processes are also playing a vital role in market growth. The industry is witnessing a shift towards more sustainable and cost-effective refining methods, such as hydrometallurgical and electrochemical processes, which offer higher recovery rates and lower environmental impact compared to traditional pyrometallurgical methods. These innovations are not only enhancing the efficiency of metal extraction and purification but are also enabling the recycling of spent batteries, thereby contributing to a circular economy. The increasing focus on environmental sustainability and resource efficiency is prompting market players to invest in research and development, further accelerating the evolution of the battery metals refining sector.

Regionally, Asia Pacific remains the dominant force in the global battery metals refining market, accounting for the largest share due to its robust manufacturing ecosystem, abundant raw material resources, and the presence of leading battery producers in China, Japan, and South Korea. North America and Europe are also witnessing significant growth, driven by policy support for electric mobility, investments in local battery supply chains, and initiatives to reduce dependence on imported raw materials. Meanwhile, Latin America and the Middle East & Africa are emerging as important players, particularly as sources of raw materials and as regions investing in refining capabilities to capture more value within their borders.

As the battery metals refining market continues to evolve, the introduction of a Battery Metals Spot Trading Platform could revolutionize the way these critical materials are bought and sold. Such a platform would provide a centralized marketplace for trading refined metals like lithium, cobalt, nickel, and manganese, offering greater transparency and efficiency in pricing. By facilitating real-time transactions and providing market participants with up-to-date information on supply and demand dynamics, a spot trading platform could enhance liquidity and reduce price volatility. This innovation would be particularly beneficial for manufacturers and refiners seeking to optimize their

LME Index rose to 4,700 Index Points on October 29, 2025, up 0.79% from the previous day. Over the past month, LME Index's price has risen 7.33%, and is up 13.22% compared to the same time last year, according to trading on a contract for difference (CFD) that tracks the benchmark market for this commodity. LME Index - values, historical data, forecasts and news - updated on December of 2025.

This dataset provides high-resolution Kikuchi diffraction patterns and associated orientation mapping data collected from both wrought and as-built additively manufactured (AM) Inconel 718 superalloys. The dataset includes raw electron backscatter diffraction (EBSD) patterns stored as .tif images and organized through .up2 metadata files, along with processed orientation data in .ang format. These measurements were acquired using a high-sensitivity EBSD detector over large scan areas, enabling detailed spatial resolution of microstructural features such as grain orientations, subgrain boundaries, and processing-induced texture. The dataset supports a range of applications, including machine learning for pattern recognition and the development of robust indexing algorithms. By including both wrought and AM material states, this dataset offers valuable insight into the influence of manufacturing route on crystallographic texture and cellular dislocation structure in Inconel 718, a critica..., Materials and Sample Preparation: Three different nickel-based superalloys were used in this study: a wrought recrystallized Inconel 718 (30 minutes at 1050°C followed by 8 hours at 720°C) with chemical composition of (wt.%) Ni – 0.56% Al – 17.31% Fe – 0.14% Co – 17.97% Cr – 5.4% Nb + Ta – 1.00% Ti – 0.023% C – 0.0062% N; a 3D-printed Inconel 718 by DED (as-built) and a dynamically recrystallized Waspalloy (heat-treated) characterized by a necklace microstructure. The 3D-printed material was produced using a Formalloy L2 Directed Energy Deposition (DED) unit utilizing a 650 W Nuburu 450 nm blue laser capable of achieving a 400 μm laser spot size. Argon was used as the shielding and carrier gas, and the specimen remained in its as-built condition. The chemical composition is in wt.%: Ni – 0.45% Al – 18.77% Fe – 0.07% Co – 18.88% Cr – 5.08% Nb – 0.96% Ti – 0.036% C – 0.02% Cu - 0.04% Mn - 0.08% Si - 3.04% Mo. All samples were machined by EDM as flat dogbone samples of gauge section 1 × 3..., # Kikuchi pattern dataset from wrought and as-built additively manufactured superalloys

Dataset DOI: 10.5061/dryad.zcrjdfnr9

Description of the data and file structure

Files Provided:

See the Methods section for a description of file naming patterns and meaning.

Folder architecture:

718RX:

• 1um
  • 718RX_1um.ang
  • 718RX_1um_sharpness.tif
  • 718RX_1um_CI.tif
  • 718RX_1um_IQ.tif
  • 718RX_1um_SEM.tif
  • IPF_mtex.jpg
  • 718RX_1um_IPF_X.jpg
  • 718RX_1um_IPF_Y.jpg
  • 718RX_1um_IPF_Z.jpg
  • 718RX_1um_480x480.up2
  • 718RX_1um_120x120.up2
  • 718RX_1um_120x120_preprocessed.up2
• 0.1um_1
  • 718RX_0.1um_1.ang
  • 718RX_0.1um_1_sharpness.tif
  • 718RX_0.1um_1_CI.tif
  • 718RX_0.1um_1_IQ.tif
  • 718RX_0.1um_1_SEM.tif
  • IPF_mtex.jpg
  • 718RX_0.1um_1_IPF_X.jpg
  • 718RX_0.1um_1_IPF_Y.jpg
  • 718RX_0.1um_1_IPF_Z.jpg
  • 718RX_0.1um_1_480x480.up2
  • 718RX_0.1um_1_120x120.up2
  • 718RX_0.1um_1_120x120_preprocessed.up2
• 0.1um_2
  • 718RX_0.1...,