Pyritic Mineralogy Instrumentation in 2025: The Next-Gen Tools and Technologies Set to Revolutionize Ore Analysis. Discover Who’s Leading, What’s Changing, and How You Can Benefit.

• Executive Summary: 2025–2029 Market Outlook
• Key Drivers & Challenges in Pyritic Mineralogy Instrumentation
• Technology Advances: Next-Gen Analytical Tools and Methods
• Leading Manufacturers and New Entrants (with Official Sources)
• Regional Market Trends: Growth Hotspots and Investment Focus
• Applications Across Mining, Geology, and Environmental Sectors
• Competitive Landscape: Strategic Moves and Partnerships
• Regulatory & Industry Standards: Compliance and Innovation
• Market Forecasts: Revenue, Demand, and Adoption Trends to 2029
• Future Outlook: Emerging Opportunities and Disruptive Technologies
• Sources & References

Executive Summary: 2025–2029 Market Outlook

The market for pyritic mineralogy instrumentation is poised for dynamic evolution from 2025 through 2029, driven by the growing demand for advanced geochemical characterization across mining, environmental monitoring, and materials research. Pyrite (FeS₂) is critical not only as an indicator mineral in ore genesis but also due to its role in acid mine drainage and environmental impact assessments. As exploration activities intensify globally, especially in regions rich in sulfide mineralization, the need for precise, rapid, and reliable instrumentation is accelerating.

Key instrumentation categories encompass X-ray diffraction (XRD), scanning electron microscopy (SEM) with energy-dispersive X-ray spectroscopy (EDS), automated mineralogy systems, and portable analyzers. Established manufacturers such as Bruker Corporation and Thermo Fisher Scientific are expected to maintain their technological leadership, offering high-throughput XRD and advanced electron microscopy platforms. Carl Zeiss AG continues to innovate in SEM and microanalysis, supporting detailed pyrite grain characterization and textural studies crucial for both exploration and environmental management.

Automated mineralogy solutions, notably those from FEI Company (now part of Thermo Fisher Scientific), have seen increased adoption in mining due to their ability to generate quantitative mineral maps and automate identification of pyrite and associated gangue minerals. This trend is projected to remain strong through 2029 as mining companies seek efficiencies in ore characterization and process optimization. Meanwhile, the push for field-deployable instrumentation is fostering growth in portable XRF and Raman analyzers, with companies like Olympus Corporation and Renishaw plc investing in ruggedized solutions for in-situ analysis.

The regulatory emphasis on environmental stewardship—particularly monitoring acid rock drainage—increases demand for pyrite quantification in waste rock and tailings. This has prompted new partnerships between instrument manufacturers and mining operators to develop tailored analytical workflows. Furthermore, digitalization initiatives, including cloud-based data management and AI-assisted mineral identification, are expected to gain traction, with manufacturers such as Bruker Corporation and Thermo Fisher Scientific exploring integration of software platforms for streamlined mineralogical data interpretation.

Overall, the 2025–2029 outlook for pyritic mineralogy instrumentation is one of robust growth, propelled by global exploration, environmental compliance requirements, and rapid technological advancements. The sector is characterized by innovation from established leaders and new entrants, with an emphasis on automation, portability, and digital integration to meet the evolving needs of the mining and geosciences communities.

Key Drivers & Challenges in Pyritic Mineralogy Instrumentation

The landscape of pyritic mineralogy instrumentation in 2025 is shaped by several key drivers and challenges, reflecting both technological advancements and evolving industry demands. Pyrite, an iron sulfide mineral, is central to a range of mining, environmental, and geochemical applications, making its accurate identification and quantification crucial.

Key Drivers:

• Environmental Regulations: Stricter environmental mandates, particularly concerning acid mine drainage (AMD), are compelling mining companies to adopt more precise and rapid pyrite detection systems. Accurate characterization of pyrite content is essential for mitigation strategies, driving demand for advanced instrumentation.
• Technological Innovation: The introduction of high-resolution analytical tools, such as advanced X-ray diffractometers and automated scanning electron microscopes (SEM), is enhancing the speed and accuracy of mineralogical analyses. Leading manufacturers like Bruker and Thermo Fisher Scientific are at the forefront, developing instruments capable of rapid, automated, and multi-elemental analysis tailored for pyrite and associated minerals.
• Digital Transformation: Integration of artificial intelligence (AI) and cloud-based data management systems is streamlining mineralogical workflows. Companies such as Carl Zeiss AG are leveraging machine learning for automated phase identification, reducing manual intervention and improving reproducibility.
• Resource Efficiency: As lower-grade ore bodies become economically viable, precise mineralogical mapping—especially for sulfide minerals like pyrite—enables optimized processing, contributing to operational efficiency and cost reduction.

Key Challenges:

• Sample Complexity: Pyritic ores often exhibit complex intergrowths with other sulfides and silicates, making phase discrimination challenging. Instruments require advanced image analysis and spectral deconvolution capabilities to address these complexities.
• Cost and Accessibility: High-end analytical instruments from companies like Bruker, Thermo Fisher Scientific, and Carl Zeiss AG involve significant capital investment, limiting access for smaller operations or research laboratories.
• Data Management: The sheer volume and complexity of mineralogical data generated by modern instruments pose challenges for storage, interpretation, and integration with existing mine management systems. This necessitates robust digital infrastructure and expertise.
• Standardization: Industry-wide standards for pyrite quantification and reporting remain under development, making cross-comparison of results between laboratories and sites difficult.

Looking ahead, the sector is poised for further growth as automation, miniaturization, and cloud-based platforms become standard. However, ensuring accessibility, affordability, and standardization will be critical to realizing the full potential of pyritic mineralogy instrumentation in the coming years.

Technology Advances: Next-Gen Analytical Tools and Methods

The landscape of pyritic mineralogy instrumentation is rapidly evolving in 2025, driven by the mining sector’s increasing demand for precision, speed, and automation in the analysis of sulfide ore bodies. As pyrite (FeS₂) is both a valuable ore and a source of environmental challenges (e.g., acid mine drainage), the ability to characterize its occurrence, texture, and chemistry is essential for resource optimization and sustainable operations.

A major trend is the widespread adoption of advanced X-ray diffraction (XRD) and X-ray fluorescence (XRF) technologies, enabling in-situ and real-time mineralogical mapping. Companies like Bruker and Evident (formerly Olympus IMS) are at the forefront with portable, ruggedized instruments capable of field deployment. These systems provide rapid, non-destructive mineral identification—critical for distinguishing pyrite from similar sulfides, estimating relative abundances, and guiding drilling decisions. Handheld XRF analyzers, for instance, are now capable of delivering near-laboratory quality results on-site, streamlining exploration and grade control workflows.

Recent years have seen notable advances in automated mineralogy platforms, particularly those based on scanning electron microscopy (SEM) integrated with energy-dispersive X-ray spectroscopy (EDS). Carl Zeiss AG and Thermo Fisher Scientific offer state-of-the-art systems that automate particle-by-particle analysis, providing detailed textural and compositional data for pyrite and associated sulfides. These instruments deliver high-throughput mineral liberation analyses, supporting both metallurgical optimization and environmental risk assessments.

Spectroscopic approaches are also gaining traction. Near-infrared (NIR) and Raman spectrometers, such as those developed by HORIBA, are being deployed to rapidly differentiate pyrite from marcasite and other polymorphs, as well as to monitor surface weathering processes. These instruments are increasingly integrated into mine site workflows, supporting both exploration and remediation efforts.

Looking ahead to the next few years, the sector anticipates further integration of artificial intelligence and machine learning algorithms into analytical workflows. Automated mineral identification, anomaly detection, and predictive modeling are expected to enhance the interpretive power of mineralogical datasets. Additionally, collaborative efforts between instrument manufacturers and mining companies are driving the push for more robust, networked, and remotely operated platforms—enabling real-time decision-making from core shed to control room.

In summary, the next generation of pyritic mineralogy instrumentation in 2025 is defined by greater automation, field deployability, multi-modal analysis, and data-driven intelligence, with key contributions from leading companies including Bruker, Evident, Carl Zeiss AG, Thermo Fisher Scientific, and HORIBA.

Leading Manufacturers and New Entrants (with Official Sources)

The instrumentation landscape for pyritic mineralogy is evolving rapidly, driven by both established manufacturers and a cohort of new entrants seeking to address emerging analytical demands in mining, environmental monitoring, and geoscience. In 2025, leading global manufacturers such as Bruker, Thermo Fisher Scientific, and Oxford Instruments remain dominant, leveraging decades of expertise in X-ray diffraction (XRD), X-ray fluorescence (XRF), and electron microscopy technologies critical for pyrite characterization.

Bruker is recognized for its advanced XRD and micro-XRF platforms, such as the D8 series and M4 TORNADO, widely deployed in mineralogical laboratories for phase identification and trace element mapping of pyrite and associated sulfides. Thermo Fisher Scientific continues to expand its suite of portable and benchtop XRF analyzers, such as the Niton series, which allow in-situ pyrite quantification and sulfur analysis in the field, as well as SEM-EDS (scanning electron microscope with energy dispersive spectroscopy) solutions for high-resolution mineralogical investigation. Oxford Instruments is prominent for its electron backscatter diffraction (EBSD) and X-ray microanalysis systems, providing crystallographic and compositional insights into pyrite morphology and paragenesis.

European firms like Malvern Panalytical have also consolidated their presence, offering integrated solutions such as the Aeris and Zetium platforms for rapid, automated XRD/XRF mineral identification and quantification. In parallel, Japanese manufacturer Hitachi High-Tech Corporation is recognized for robust benchtop and handheld XRF and SEM systems that are increasingly adopted for ore grade control and environmental assessments of pyritic minerals.

The sector is also witnessing new entrants and innovation-driven startups, particularly in the domain of hyperspectral imaging and AI-powered mineral analytics. Companies such as Resonon and Specim, Spectral Imaging are introducing hyperspectral cameras capable of rapid, non-destructive mapping of pyritic mineralogy in drill core and hand specimen, with software for automated mineral classification. Meanwhile, firms like Carl Zeiss AG are expanding digital mineralogy solutions by integrating advanced imaging with data analytics to streamline pyrite identification workflows.

Looking ahead, the next few years will likely see increased collaboration between traditional instrument makers and new technology developers, with a focus on automation, cloud-based data management, and real-time mineralogical analysis. This is expected to further lower analytical barriers for mining companies, research institutions, and environmental agencies seeking precise and efficient pyrite assessment.

Regional Market Trends: Growth Hotspots and Investment Focus

The global market for pyritic mineralogy instrumentation is experiencing a dynamic phase in 2025, with growth hotspots emerging across key mining and mineral processing regions. The demand for advanced analytical tools to characterize pyrite and associated sulfide minerals is being propelled by both resource exploration and environmental monitoring imperatives. Several regions stand out for their accelerated investments and adoption of state-of-the-art mineralogy instrumentation.

In North America, particularly Canada and the United States, robust mining activity in gold, copper, and base metals continues to drive the need for real-time, high-precision mineral identification. Mining companies are increasingly adopting portable X-ray fluorescence (pXRF) and automated quantitative mineralogy systems to improve ore characterization and optimize processing. Leading instrumentation manufacturers, such as Thermo Fisher Scientific and Bruker Corporation, have reported strong demand for their mineral analyzers in these markets, with investments focusing on improving throughput and data integration capabilities.

Australia remains a growth epicenter, leveraging its vast resource base and advanced mining sector. The deployment of automated mineralogical analysis, including scanning electron microscopy (SEM)-based systems and laser-induced breakdown spectroscopy (LIBS), is widespread in both exploration and environmental applications. Companies such as Carl Zeiss AG and Evident Corporation (formerly Olympus Scientific Solutions) are expanding their presence, providing solutions customized for pyrite and sulfide mineral studies. Notably, Australian research institutions and service laboratories are also investing in integrated platforms for in-situ and laboratory-based mineralogical workflows.

In South America, especially Chile and Peru, the mining sector’s expansion has prompted substantial upgrades in mineralogical instrumentation. The focus here is on maximizing resource recovery and managing acid mine drainage risks through precise pyrite quantification. Regional initiatives are fostering partnerships between global equipment suppliers and local service providers, with Malvern Panalytical and Hitachi High-Tech Corporation actively supporting these markets.

Looking ahead, the outlook for 2025 and the next several years suggests continued geographic diversification of investment. Emerging markets in Africa—South Africa, Ghana, and Zambia—are seeing increased adoption of portable and benchtop mineral analyzers as exploration intensifies. Furthermore, the integration of cloud-based data platforms and AI-driven mineral identification is expected to accelerate, with instrumentation leaders investing in digital transformation and remote analysis capabilities. As environmental regulations tighten and the complexity of ore bodies increases, regional markets that prioritize advanced pyritic mineralogy solutions are likely to attract the bulk of new investments and innovation in instrumentation.

Applications Across Mining, Geology, and Environmental Sectors

Pyritic mineralogy instrumentation is playing an increasingly pivotal role across mining, geology, and environmental sectors as of 2025, reflecting the growing demand for precise mineral characterization and monitoring. Pyrite—an iron sulfide mineral—occurs ubiquitously in ore deposits and sedimentary basins. Its identification and quantification are critical for resource estimation, process optimization, and environmental risk mitigation.

In mining, real-time mineralogical analysis of pyrite is essential for both exploration and ore processing. Automated mineralogy systems, such as QEMSCAN and MLA (Mineral Liberation Analyzer), integrate scanning electron microscopy (SEM) with energy-dispersive X-ray spectroscopy (EDS) to deliver rapid, quantitative insights into pyrite textures and associations. Global manufacturers like Carl Zeiss AG and Thermo Fisher Scientific have been at the forefront, providing advanced SEM-EDS platforms tailored for mining operations. These systems are widely adopted at mine sites and core sheds, enabling geologists and metallurgists to optimize ore blending, flotation, and downstream processing.

Portable X-ray fluorescence (pXRF) analyzers are another increasingly utilized tool for field-based pyrite identification and semi-quantitative analysis. Companies such as Olympus Corporation and Hitachi High-Tech Corporation supply rugged pXRF units capable of rapid elemental screening directly in drill cores, outcrops, or tailings. While pXRF cannot distinguish between sulfide minerals with overlapping elemental signatures, it offers valuable first-pass data to guide detailed laboratory analysis.

In geological research, laser ablation inductively coupled plasma mass spectrometry (LA-ICP-MS) is widely employed for in-situ trace element mapping within pyrite grains, aiding in genetic interpretations of ore deposits. Leading instrument suppliers such as Agilent Technologies and PerkinElmer Inc. support research laboratories with high-sensitivity LA-ICP-MS systems compatible with mineralogical applications.

Environmental monitoring is another sector driving demand for pyritic mineralogy instrumentation, particularly due to concerns about acid mine drainage (AMD). Quantifying pyrite content in mine waste is vital for predicting AMD potential and informing remediation. Automated mineralogy and X-ray diffraction (XRD) instruments, manufactured by Bruker Corporation and Rigaku Corporation, are routinely used for this purpose in consulting laboratories and regulatory agencies.

Looking ahead, the next few years are likely to see further integration of artificial intelligence and machine learning in pyritic mineralogy instrumentation, enhancing data processing speed and pattern recognition. Cloud-based platforms for remote access and collaborative analysis are also expected to become more widespread, driven by ongoing innovation among established players and new entrants alike.

Competitive Landscape: Strategic Moves and Partnerships

The competitive landscape for pyritic mineralogy instrumentation in 2025 is shaped by a combination of established instrumentation giants, rising specialist manufacturers, and strategic collaborations aimed at technological advancement, market penetration, and data integration. As demand grows for precise pyrite characterization—driven by mining, environmental monitoring, and resource exploration—key players are intensifying efforts to consolidate their positions through product innovation, acquisitions, and partnerships.

Among the global leaders, Thermo Fisher Scientific continues to expand its X-ray diffraction (XRD) and X-ray fluorescence (XRF) portfolio, often regarded as benchmarks for mineralogical analysis, with recent releases focusing on automation and real-time analytics for pyritic ores. The company’s integration of AI-driven software for mineral phase identification exemplifies the trend toward smarter, faster, and more user-friendly instrumentation. Similarly, Bruker retains a strong market presence through advancements in micro-XRF and Raman spectroscopy platforms, with ongoing partnerships aimed at developing portable solutions for field-based pyrite analysis.

European manufacturers, such as Malvern Panalytical, are leveraging their expertise in automated mineralogy systems. Their collaborations with mining and environmental remediation firms highlight a strategic pivot toward integrated workflows, where pyritic mineral data is seamlessly coupled with process optimization tools. Notably, Carl Zeiss AG has expanded its reach through partnerships in the field of automated mineralogy, utilizing advanced scanning electron microscopy (SEM) for high-resolution pyrite imaging and quantification.

Specialized entrants and regional players are also making their mark. For instance, Oxford Instruments is enhancing modularity and miniaturization in its mineral analyzers, targeting niche applications such as acid mine drainage prediction and rapid pyrite mapping. These moves are often supported by supply agreements with mining operators or joint development programs with governmental geological surveys.

Strategic alliances are expected to intensify in the coming years. Collaborations between instrumentation manufacturers and software developers are central, with open data standards and cloud-based analytics becoming focal points for competitive differentiation. Furthermore, joint ventures between equipment providers and mining technology companies are anticipated to accelerate, facilitating the deployment of real-time, in-situ pyrite monitoring systems across global mining hubs. With environmental regulations tightening and the economic imperative for resource efficiency growing, the competitive landscape for pyritic mineralogy instrumentation is poised for both consolidation among market leaders and the emergence of agile, innovation-driven partnerships.

Regulatory & Industry Standards: Compliance and Innovation

The regulatory landscape for pyritic mineralogy instrumentation in 2025 is shaped by heightened scrutiny over environmental and safety standards, particularly due to the implications of pyrite oxidation in mining, construction, and waste management. Instrumentation used for pyrite detection and quantification—such as X-ray diffraction (XRD), scanning electron microscopy (SEM) with energy-dispersive X-ray spectroscopy (EDS), and portable mineral analyzers—must adhere to guidelines set by both national and international regulatory bodies. Organizations like the International Organization for Standardization (ISO) and ASTM International continue to update standards (e.g., ISO 13320 for particle size analysis, ASTM D7621 for sulfur forms) to ensure consistency, reliability, and environmental compliance.

Manufacturers of mineralogy instrumentation, notably Bruker and Thermo Fisher Scientific, are actively engaging with regulatory evolution by integrating advanced analytical capabilities and automated compliance features into their platforms. Bruker, known for its comprehensive XRD and microanalysis solutions, has focused on enhancing detection limits for trace pyrite and developing robust software for regulatory reporting. Thermo Fisher Scientific, a leader in portable XRF and laboratory-based analysis, has introduced instruments with improved real-time data logging and traceability features, supporting compliance with environmental monitoring regulations.

In the European Union and Australia, regulatory requirements for acid sulfate soil assessment and mine waste characterization have become more stringent, driving demand for accurate, field-deployable instrumentation. Instrument manufacturers are responding with innovations that enable operators to perform rapid, on-site mineralogical assessments, reducing delays in compliance verification and reporting. Industry-specific standards, such as those enforced by International Council on Mining and Metals (ICMM) and regional mining authorities, emphasize not only analytical accuracy but also robust data management and chain-of-custody protocols.

Looking ahead, the next few years are expected to see further harmonization of global standards and increased digitalization of compliance processes. The adoption of cloud-based data integration, remote calibration, and automated regulatory reporting is anticipated to accelerate, as instrumentation providers like Olympus Corporation and Malvern Panalytical invest in connected laboratory solutions. This evolution will likely reduce the administrative burden on operators and enhance the traceability and transparency of pyrite analysis across mining, environmental consultancy, and construction sectors. As regulatory frameworks continue to evolve, industry collaboration with standard-setting bodies will remain crucial to ensure instrumentation keeps pace with compliance and innovation imperatives.

Market Forecasts: Revenue, Demand, and Adoption Trends to 2029

The global market for pyritic mineralogy instrumentation is poised for steady growth through 2029, driven by increasing demand across mining, environmental monitoring, and geochemical research sectors. As of 2025, the acceleration of mineral exploration projects, particularly for gold and base metals where pyrite is a key indicator mineral, is fueling sales of advanced analytical systems. Major mining economies—including Australia, Canada, China, and South Africa—are investing in precise mineral analysis tools to optimize extraction and comply with evolving environmental standards.

Demand for high-throughput, automated instrumentation—such as scanning electron microscopes (SEM) with energy-dispersive X-ray spectroscopy (EDS), and X-ray diffraction (XRD) systems—is rising. Industry leaders like Thermo Fisher Scientific and Bruker continue to upgrade their mineralogy platforms, integrating artificial intelligence (AI) and automation to provide faster, more accurate characterization of pyrite-bearing samples. These enhancements are expected to drive revenue growth by reducing the need for manual sample preparation and interpretation.

Another important trend is the adoption of portable and field-deployable instruments. Manufacturers such as Olympus and Hitachi High-Tech Corporation have expanded their product lines to include handheld X-ray fluorescence (XRF) analyzers capable of rapid, in-situ pyrite identification. These portable instruments are increasingly favored for on-site exploration and environmental assessments, supporting higher adoption rates in remote and developing regions where laboratory infrastructure may be limited.

Revenue streams are also benefiting from the growing use of pyritic mineralogy instrumentation in acid mine drainage (AMD) prediction and remediation. Environmental regulations in North America and Europe require mining operators to evaluate and mitigate AMD risks, leading to higher procurement of analytical equipment for monitoring sulfide mineral content, including pyrite.

Looking ahead to 2029, the market is expected to witness compounded annual growth in the mid-to-high single digits, as global mining output recovers and sustainability requirements intensify. Emerging markets in Latin America and Africa are projected to contribute significantly to demand, while established markets in Europe and North America will be driven by regulatory compliance and the modernization of laboratory infrastructures. Companies like Malvern Panalytical and Carl Zeiss AG are likely to expand their offerings of advanced mineralogy solutions to capitalize on these trends.

• Increased automation and AI integration are key differentiators in new instrument launches.
• Field-deployable and portable solutions to outpace traditional benchtop sales in certain markets.
• Environmental monitoring and sustainable mining practices will continue to drive adoption.

Future Outlook: Emerging Opportunities and Disruptive Technologies

The landscape of pyritic mineralogy instrumentation is poised for significant transformation in 2025 and the coming years, driven by advances in analytical technologies and the growing demand for precise, real-time mineral identification. One of the primary trends is the integration of artificial intelligence (AI) and machine learning with existing mineralogical instruments, enabling faster, automated identification and quantification of pyrite and associated sulfide phases. This is particularly relevant for mining operations, where rapid on-site analysis can drastically improve resource estimation and ore processing efficiency.

Instrumentation leaders such as Bruker and Thermo Fisher Scientific are at the forefront of deploying advanced X-ray diffraction (XRD), X-ray fluorescence (XRF), and scanning electron microscopy (SEM) platforms. These systems are increasingly equipped with automated mineralogy software, such as Bruker’s QUANTAX and Thermo Fisher’s Mineral Liberation Analyzer (MLA), allowing for seamless, high-throughput characterization of pyritic ores. Recent updates to these platforms have focused on improving analytical speed, reducing sample preparation time, and enhancing the detection of trace elements and mineral inclusions—factors critical for both exploration and environmental monitoring.

Raman spectroscopy, another rapidly evolving tool, is being adapted for in-situ and field-based applications. Companies like Renishaw are developing portable Raman systems that combine robust hardware with cloud-based data processing, opening new possibilities for geologists to identify pyrite and related minerals directly at the outcrop or drill core. The miniaturization of such instruments and the integration of wireless connectivity are expected to improve accessibility and adoption rates across the mining and environmental sectors.

The push towards sustainability and responsible mining is also driving innovation in pyritic mineralogy instrumentation. Automated drone-mounted sensors and hyperspectral imaging technologies, supported by organizations like Agilent Technologies and Carl Zeiss, are enabling non-destructive, large-scale mapping of pyritic mineralization in both active and legacy mine sites. Such remote sensing platforms are anticipated to become more prevalent through 2025–2027 as costs decrease and data processing capabilities expand.

Looking ahead, the convergence of AI-driven analytics, portable instrumentation, and remote sensing technologies is set to disrupt traditional workflows in pyritic mineralogy. The market is expected to see increased collaboration between instrument manufacturers, mining companies, and technology startups, fostering a competitive environment for rapid innovation and deployment of next-generation mineralogical tools.

Sources & References

• Bruker Corporation
• Thermo Fisher Scientific
• Carl Zeiss AG
• FEI Company
• Olympus Corporation
• Renishaw plc
• Evident (formerly Olympus IMS)
• HORIBA
• Oxford Instruments
• Malvern Panalytical
• Hitachi High-Tech Corporation
• Resonon
• Specim, Spectral Imaging
• PerkinElmer Inc.
• Rigaku Corporation
• International Organization for Standardization
• ASTM International
• International Council on Mining and Metals