Britain's path to mineral independence begins with a comprehensive understanding of the strategic importance of domestic resource development. The UK Critical Minerals Strategy represents a fundamental shift from import dependency toward self-reliance in materials essential for modern technology, defense systems, and clean energy infrastructure. Furthermore, this strategic framework addresses vulnerabilities in global supply chains while positioning the UK for long-term economic security and technological sovereignty.
Understanding the UK's Strategic Mineral Independence Framework
Modern technological advancement increasingly depends on specialised materials extracted from the Earth's crust, yet few nations maintain comprehensive strategies for securing these resources domestically. The intricate web of global supply chains that deliver essential minerals to manufacturing hubs creates vulnerabilities that extend far beyond economic considerations into the realm of national security and technological sovereignty.
Defining Critical Minerals in the UK Context
The UK government employs a sophisticated multi-criteria assessment framework to identify critical minerals, evaluating three primary dimensions: supply risk, economic importance, and substitutability potential. Materials classified as critical must demonstrate high economic significance for key industries while facing substantial supply chain vulnerabilities and limited alternative sourcing options.
These materials power modern technology infrastructure across multiple sectors, from consumer electronics requiring rare earth elements for miniaturised components to renewable energy systems demanding specialised alloys for efficient operation. The strategic importance extends beyond commercial applications into defence systems, advanced manufacturing processes, and emerging technologies essential for maintaining competitive advantages in global markets.
The 2035 Vision: Key Targets and Measurable Outcomes
The UK Critical Minerals Strategy establishes specific quantitative targets designed to transform the nation's resource independence trajectory by 2035. The framework centres on three interconnected objectives that collectively address different aspects of supply chain resilience and domestic capability development.
The domestic production target seeks to achieve 10% of national demand through UK-based extraction and processing operations, representing a fundamental shift from current import-dependent supply patterns. This ambitious goal requires substantial investment in exploration activities, extraction infrastructure, and processing capabilities across multiple geological regions.
Complementing primary production efforts, the strategy mandates that 20% of critical mineral supply must originate from recycling and recovery operations by 2035. This circular economy approach targets end-of-life electronics, decommissioned renewable energy infrastructure, and industrial waste streams containing recoverable mineral content.
The import diversification requirement limits dependency on any single nation to no more than 60% of supply for individual critical minerals. This risk mitigation mechanism addresses current vulnerabilities where certain materials face extreme concentration in specific geographic regions, potentially exposing the UK to supply disruptions from geopolitical tensions, natural disasters, or trade restrictions.
How Does China's Market Dominance Shape UK Mineral Security?
Global mineral supply chains exhibit unprecedented concentration levels that create systematic vulnerabilities for importing nations worldwide. This concentration phenomenon particularly affects rare earth elements, battery materials, and specialised metals essential for advanced technology applications, where processing capabilities remain concentrated in specific geographic regions despite more distributed raw material extraction.
Quantifying Global Supply Chain Concentration
Current market structure analysis reveals concerning dependency levels across multiple critical mineral categories. China maintains approximately 70% market share in rare earth mining operations globally, controlling extraction from both domestic deposits and international operations through technological expertise and infrastructure investments.
Processing capacity concentration presents even more severe vulnerabilities, with China commanding an estimated 90% of global rare earth refining operations. This downstream bottleneck means that even rare earth materials mined in other nations typically require processing through Chinese facilities before reaching end-use applications in technology manufacturing.
Lithium processing capabilities show similar concentration patterns, with approximately 60% of global lithium conversion capacity located within Chinese industrial facilities. This processing stage transforms raw lithium compounds into battery-grade materials suitable for electric vehicle applications and energy storage systems.
Tungsten production demonstrates the most severe concentration levels, with China controlling an estimated 85% of global tungsten supply chains. This strategic metal finds critical applications in defence systems, advanced manufacturing tools, and specialised alloy production for aerospace applications.
Geopolitical Risk Assessment for UK Supply Lines
Single-point-of-failure scenarios in global trade networks create systematic risks extending beyond normal market volatility into potential strategic vulnerabilities. Supply disruptions affecting critical minerals could cascade through multiple technology sectors simultaneously, affecting everything from automotive manufacturing to renewable energy deployment timelines.
Economic warfare implications emerge when essential materials face extreme supply concentration, potentially providing leverage mechanisms in international disputes. Historical precedents demonstrate how mineral export restrictions can impact downstream industries across multiple nations, affecting both commercial competitiveness and defence capabilities.
Strategic autonomy requirements become particularly acute for defence applications, where supply chain assurance takes precedence over cost optimisation considerations. Advanced military systems require consistent access to specialised materials that may face disruption during periods of international tension or strategic competition.
What Are the UK's Domestic Critical Mineral Assets and Production Capabilities?
Mapping Britain's Untapped Mineral Wealth
The UK possesses significant geological resources distributed across multiple regions, each offering distinct advantages for different mineral categories and processing approaches. These domestic deposits provide foundation assets for developing integrated supply chains that could substantially reduce import dependency while creating regional economic development opportunities.
Cornwall's Lithium Potential: Europe's Largest Deposit
Cornwall's granite formations contain substantial lithium mineralisation that represents one of Europe's most significant lithium resources. The Cornubian Batholith geological structure extends across much of southwestern England, providing multiple potential extraction sites with varying mineral grades and processing requirements.
Geological surveys indicate lithium concentrations suitable for commercial extraction using hard rock mining methodologies rather than brine processing approaches employed in South American operations. This extraction approach requires different technical expertise and processing infrastructure but offers advantages in terms of processing control and environmental impact management.
Commercial production viability depends on several factors including extraction costs, processing efficiency, environmental permitting process essentials, and market price stability. Current exploration activities suggest potential for multiple extraction operations across different granite intrusions, providing resource diversity and operational redundancy for domestic supply development.
Wales' Industrial Mineral Infrastructure
Wales maintains established industrial infrastructure supporting critical mineral processing operations, building on decades of mining and metallurgical expertise developed through traditional heavy industry operations. This existing capability provides advantages for developing critical mineral processing capacity without requiring complete infrastructure development from initial stages.
The Clydach nickel refinery facility in Swansea represents one of Europe's significant nickel processing operations, providing technological expertise and infrastructure that could support expanded critical mineral processing activities. This facility's strategic location and established workforce offer foundation assets for developing integrated processing capabilities.
Tungsten resources distributed across Wales provide potential domestic supply sources for this strategically important metal. Historical mining operations demonstrate geological potential, though modern extraction approaches would require updated environmental management practices and processing technologies optimised for current market requirements.
Rare earth alloy production capabilities position the UK as the only Western nation maintaining specialised processing capacity for permanent magnet materials used in wind turbines and advanced defence systems. This unique capability provides strategic value extending beyond domestic supply considerations into international collaboration opportunities with allied nations.
Scotland's Strategic Mineral Opportunities
Scotland's diverse geology provides exploration opportunities for battery metals including lithium, cobalt, and specialised materials required for energy storage applications. Regional geological surveys continue identifying potential deposits suitable for future development as market conditions and extraction technologies evolve.
Offshore critical mineral potential represents an emerging opportunity area where deep-sea mineral resources could supplement terrestrial deposits. This nascent sector requires specialised extraction technologies and environmental assessment frameworks currently under development internationally.
Integration opportunities with renewable energy infrastructure development provide synergistic benefits where mineral extraction operations could support grid stability and energy security objectives simultaneously. Co-location strategies offer potential efficiency gains and infrastructure cost sharing across multiple industrial activities.
Industrial Recycling Revolution: The 20% Target Strategy
Urban Mining Economics: Recovering Value from Waste
Electronic waste streams contain higher concentrations of precious metals and rare earth elements than many traditional mining operations, creating economic opportunities for sophisticated recovery operations. Mobile phones typically contain approximately 40-50 grams of gold per tonne compared to conventional ore grades of 5-10 grams per tonne in primary mining operations.
Key Insight: Urban mining from electronic waste offers unique advantages including consistent material composition, predictable supply streams, and reduced environmental impact compared to primary extraction operations, while supporting circular economy objectives.
The diversity of elements recoverable from electronic waste includes up to 60 different materials ranging from precious metals to rare earth elements and specialty alloys. This elemental complexity requires sophisticated separation technologies but provides opportunities for recovering multiple valuable materials from single processing operations.
Recovery economics depend on several factors including collection efficiency, sorting accuracy, processing technology performance, and commodity price levels. Current market conditions increasingly favour recycling operations as primary mining costs increase and environmental regulations tighten globally.
Circular Economy Integration for Critical Materials
End-of-life vehicle battery recycling breakthrough processing systems represent emerging opportunities for recovering lithium, cobalt, nickel, and manganese from electric vehicle batteries reaching retirement age. Processing technologies include thermal treatment and hydrometallurgical approaches that can recover battery-grade materials suitable for manufacturing new batteries.
Wind turbine magnet recovery programmes target permanent magnets containing neodymium, dysprosium, and other rare earth elements from decommissioned renewable energy installations. Although current volumes remain limited due to the relatively recent deployment of most wind turbines, projected decommissioning rates suggest substantial material flows in future decades.
Consumer electronics take-back schemes provide systematic collection mechanisms for smartphones, laptops, and other devices containing critical minerals. These programmes require coordination between manufacturers, retailers, consumers, and processing facilities to achieve effective material recovery rates.
How Will £50 Million in Government Funding Transform UK Mineral Independence?
Government investment in critical mineral independence represents a strategic commitment to developing domestic capabilities across the entire value chain from exploration through processing to end-use applications. The £50 million funding allocation addresses market failures where private sector investment alone proves insufficient for long-term strategic development requiring substantial capital commitments and extended development timelines.
Investment Allocation Strategy Across the Value Chain
Upstream Development: Exploration and Extraction Support
Geological survey acceleration programmes receive funding support to expedite resource characterisation and reserve estimation activities across potential mineral deposits. Enhanced geological data collection reduces exploration risk and provides foundation information required for commercial development decisions.
Permitting process streamlining initiatives address regulatory barriers that historically extend development timelines and increase project costs. Investment in environmental impact assessment tools, consultation processes, and regulatory capacity building aims to maintain environmental protection standards while reducing bureaucratic delays.
Environmental impact mitigation technologies receive development support to advance sustainable extraction approaches that meet modern environmental standards. These innovations address community concerns and regulatory requirements while enabling economic resource development.
Midstream Processing: Refining Capacity Expansion
British Industrial Competitiveness Scheme applications provide financial support for processing facility development, addressing the critical bottleneck between raw material extraction and refined products suitable for manufacturing applications. Processing capacity development requires substantial capital investment and specialised technical expertise.
Technology transfer partnerships with allied nations facilitate knowledge sharing and collaborative development of advanced processing technologies. These partnerships accelerate capability development while strengthening strategic relationships with countries facing similar supply chain vulnerabilities.
Skills development programmes address workforce requirements for specialised processing roles requiring technical expertise in metallurgy, chemical processing, and advanced manufacturing techniques. Training initiatives prepare domestic workforce capacity for emerging mineral processing operations.
Downstream Applications: Manufacturing Integration
Electric vehicle battery production support connects domestic mineral processing with end-use manufacturing applications, creating integrated supply chains that capture value-added activities within the UK economy. This integration approach maximises economic benefits from domestic mineral resources.
Renewable energy component manufacturing receives investment support to develop domestic production capabilities for wind turbine components, solar panel materials, and energy storage systems requiring critical minerals. Manufacturing integration reduces import dependency while supporting clean energy transition objectives.
Defence sector supply chain resilience investments ensure strategic material access for advanced military systems including fighter aircraft, naval vessels, and sophisticated weapons systems requiring specialised materials with assured supply chains.
Public-Private Partnership Models
National Wealth Fund Integration
Risk-sharing mechanisms for mineral ventures address the high-risk nature of exploration and early-stage development activities where private sector investment may prove inadequate. Public sector participation reduces financial barriers while maintaining commercial discipline through partnership structures.
Long-term investment horizons for resource development accommodate the extended timelines required for mineral project development from exploration through commercial production. Patient capital approaches enable systematic capability development across multiple project stages.
Performance metrics for public investment returns ensure accountability and effectiveness in achieving strategic objectives while generating appropriate returns on public funds. Measurement frameworks track both financial performance and strategic independence outcomes.
What Are the Economic Implications of UK Mineral Demand Growth?
Projected Consumption Scenarios Through 2035
Copper Demand Trajectory: Infrastructure Electrification
| Application Sector | 2025 Demand | 2035 Projection | Growth Rate |
|---|---|---|---|
| Electric Vehicles | 180,000 tonnes | 420,000 tonnes | +133% |
| Renewable Energy | 95,000 tonnes | 210,000 tonnes | +121% |
| Grid Infrastructure | 140,000 tonnes | 280,000 tonnes | +100% |
Copper demand growth reflects the fundamental transformation of energy systems toward electrification across multiple sectors. Electric vehicle adoption drives substantial copper requirements for motors, wiring systems, and charging infrastructure, with each electric vehicle containing approximately three times more copper than conventional vehicles.
Renewable energy installations require significant copper content for generators, transformers, and transmission systems connecting renewable generation facilities to electrical grids. Wind turbines typically contain 3-5 tonnes of copper per megawatt of capacity, while solar installations require specialised copper alloys for electrical connections and grounding systems.
Grid infrastructure modernisation demands extensive copper installation for smart grid technologies, energy storage integration, and enhanced transmission capacity supporting renewable energy distribution. Upgraded electrical infrastructure requires premium copper products meeting strict performance specifications for reliability and efficiency.
Lithium Market Transformation: 1,100% Demand Surge Analysis
Lithium demand projections reflect the exponential growth anticipated in battery applications across transportation, energy storage, and consumer electronics sectors. The 1,100% increase by 2035 represents one of the most dramatic commodity demand growth scenarios in modern industrial history.
Electric vehicle adoption acceleration provides the primary driver for lithium demand growth, with each electric vehicle battery containing 8-15 kilograms of lithium depending on battery chemistry and vehicle size. Projected electric vehicle sales reaching 30-50% market share by 2035 creates unprecedented lithium requirements.
Energy storage system deployment requirements support grid stability as renewable energy penetration increases. Utility-scale battery installations and residential energy storage systems require substantial lithium content for grid balancing and energy transition minerals applications.
Consumer electronics market evolution continues driving baseline lithium demand for smartphones, laptops, tablets, and emerging device categories requiring portable energy storage solutions with improved performance characteristics.
Cost-Benefit Analysis of Import Reduction Strategy
Price volatility mitigation through domestic supply development provides economic stability benefits extending beyond direct cost considerations. Domestic supply capacity reduces exposure to international price fluctuations caused by supply disruptions, geopolitical tensions, or speculative trading activities.
Employment creation in regional mineral clusters generates economic multiplier effects through direct mining and processing jobs, supporting service industries, and technology development activities. Regional development benefits include infrastructure investment, skills development, and knowledge economy growth.
Technology innovation spillover effects emerge from domestic mineral industry development, creating expertise in advanced materials processing, environmental technologies, and specialised manufacturing techniques applicable across multiple industrial sectors.
Supply Chain Resilience Quantification
Risk Mitigation Value Calculation
Economic losses from supply disruption scenarios demonstrate the financial justification for domestic capability development. Historical supply interruptions in critical minerals have cost affected industries billions of dollars through production delays, alternative sourcing premiums, and market share losses.
Insurance premium reductions through supply diversification provide quantifiable benefits as companies reduce supply chain risk exposure through domestic sourcing options. Risk management benefits extend to financing costs, investment security, and strategic planning certainty.
Strategic stockpiling cost-effectiveness analysis compares inventory carrying costs with potential disruption losses, demonstrating the economic logic for maintaining strategic reserves of critical materials. Stockpiling strategies provide short-term security while domestic production capacity develops.
How Does the UK Strategy Compare to International Critical Mineral Policies?
Benchmarking Against Global Leaders
United States Critical Materials Strategy Comparison
The United States employs Defense Production Act mechanisms to accelerate critical mineral development through government authorities that can prioritise resource development for national security applications. American approaches emphasise defence sector requirements and allied partnership frameworks for supply chain diversification.
Rare earth processing capacity development programmes in the US focus on establishing non-Chinese processing facilities through public-private partnerships and direct government investment. American initiatives emphasise technological innovation and manufacturing integration for defence applications.
Allied partnership frameworks facilitate collaboration between the US, UK, Canada, and Australia for critical mineral supply chain development. These partnerships enable technology sharing, joint development projects, and coordinated strategic stockpiling initiatives.
European Union Raw Materials Act Alignment
Strategic autonomy objectives within EU policy frameworks align closely with UK independence goals, creating opportunities for coordinated development activities and shared technological innovation. European approaches emphasise circular economy integration and environmental sustainability standards.
Cross-border mineral processing collaboration enables efficiency gains through specialised facility development serving multiple national markets. EU frameworks support transnational projects that optimise processing capacity across member states and associated partners.
Regulatory harmonisation opportunities reduce barriers for UK companies operating in European markets while maintaining access to EU research funding and development programmes supporting critical mineral technologies.
Australia-Canada Partnership Models
Technology sharing agreements between Australia and Canada provide templates for UK collaboration with resource-rich allied nations. These partnerships combine Australian mining expertise with Canadian processing technologies and UK financial services capabilities.
Joint venture structures for processing facilities enable risk sharing and capital optimisation for large-scale processing operations requiring substantial investment and technical expertise. International partnerships provide scale economies and market access benefits.
Skills exchange programmes facilitate workforce development through international training initiatives and technical expertise sharing across partner nations with complementary capabilities and resource endowments.
Competitive Advantage Analysis
UK's Unique Position in Global Mineral Markets
Financial services expertise provides the UK with distinctive advantages in project financing, risk management, and investment structuring for capital-intensive mineral development projects. London's financial markets offer sophisticated funding mechanisms for resource development worldwide.
Advanced manufacturing integration capabilities connect mineral processing with high-value manufacturing applications in aerospace, automotive, and technology sectors. The UK's manufacturing base provides natural market demand for domestically processed materials.
Research and development leadership in clean technologies creates opportunities for technological innovation in sustainable extraction methods, advanced processing techniques, and environmental impact mitigation approaches.
What Challenges Could Derail the UK Critical Minerals Strategy?
Technical and Economic Barriers
Geological Complexity and Extraction Costs
Deep mining requirements for UK mineral deposits present technical challenges requiring specialised equipment, expertise, and safety systems that increase capital requirements and operational complexity. Geological conditions in the UK often necessitate sophisticated extraction approaches compared to surface mining operations available in other regions.
Environmental permitting timeline uncertainties create project development risks that could delay commercial production and increase costs through extended development periods. Complex environmental assessment requirements may require years of baseline data collection and stakeholder consultation before extraction activities commence.
Capital intensity compared to established global operations means UK projects must compete with mature mining operations in other countries that benefit from existing infrastructure, established supply chains, and optimised processing systems.
Skills Gap Analysis: Workforce Development Requirements
Mining engineering talent shortage across the UK creates recruitment challenges for projects requiring specialised technical expertise in extraction, processing, and environmental management. University programmes and professional development initiatives require expansion to meet projected workforce demands.
Specialised processing technician training needs extend beyond traditional mining skills to include advanced metallurgy, chemical processing, and automated control systems operation. Technical education programmes must develop curricula addressing critical mineral processing requirements.
International recruitment strategies may prove necessary for attracting experienced professionals from established mining jurisdictions, requiring competitive compensation packages and professional development opportunities to attract global talent.
Market Competition from Established Suppliers
Price competition from low-cost global producers presents ongoing challenges for UK operations that may face higher operating costs due to environmental standards, labour costs, and regulatory compliance requirements. Economic viability depends on achieving competitive cost structures or premium pricing for supply security benefits.
Quality standards for defence and aerospace applications require consistent material specifications and rigorous quality control systems that add complexity and cost to processing operations. Meeting stringent quality requirements may require additional investment in analytical equipment and quality assurance systems.
Customer relationship transition from import dependency involves convincing established supply chains to adopt UK sources, potentially requiring demonstration programmes, technical support, and competitive pricing during market entry phases.
Regulatory and Environmental Considerations
Planning Permission Complexity for New Operations
Local community engagement requirements involve extensive consultation processes that may extend project development timelines and require ongoing stakeholder management throughout operational phases. Community support depends on demonstrating economic benefits while addressing environmental concerns.
Environmental impact assessment timelines require comprehensive studies of potential effects on air quality, water resources, wildlife habitats, and community impacts. Assessment processes may require multiple years of baseline data collection before development permits are granted.
Integration with net-zero carbon commitments requires mineral extraction and processing operations to demonstrate compatibility with climate objectives through renewable energy use, carbon capture technologies, and environmental restoration programmes.
Critical Success Factor: The strategy's effectiveness depends on balancing rapid development timelines with comprehensive environmental protection standards, requiring innovative approaches to sustainable extraction and processing technologies.
What Are the Long-Term Strategic Implications for UK Economic Security?
Technology Sovereignty Through Mineral Independence
Defence Sector Supply Chain Resilience
F-35 fighter jet component supply security depends on reliable access to rare earth elements, titanium alloys, and specialised materials requiring assured supply chains independent of potential adversaries. Defence applications prioritise supply security over cost considerations, justifying premium pricing for domestic sources.
Naval systems critical material requirements include specialised steels, rare earth permanent magnets, and advanced composites for submarine construction, surface vessel systems, and maritime defence technologies. Naval applications require materials meeting stringent performance specifications under extreme operational conditions.
Cybersecurity infrastructure mineral dependencies include rare earth elements for data centre equipment, specialised alloys for secure communication systems, and advanced materials for quantum computing applications. Information security applications require supply chains protected from potential tampering or disruption.
Clean Energy Transition Acceleration
Wind turbine permanent magnet supply chains require neodymium, dysprosium, and other rare earth elements for efficient generator systems in offshore wind installations. Renewable energy deployment timelines depend on reliable access to specialised materials for turbine manufacturing.
Electric grid modernisation material requirements include copper for transmission systems, lithium for grid-scale energy storage, and advanced semiconductors for smart grid control systems. Grid infrastructure requires materials meeting stringent reliability and performance standards.
Hydrogen economy infrastructure mineral needs encompass platinum group metals for electrolysis systems, specialised steels for high-pressure storage, and advanced materials for fuel cell applications. Hydrogen technology deployment depends on secure access to critical materials.
Advanced Manufacturing Competitiveness
Semiconductor industry supply chain integration requires ultra-pure materials, rare earth elements, and specialised chemicals for chip manufacturing processes. Semiconductor production demands materials meeting extremely stringent purity and consistency specifications.
Quantum technology development material access includes specialised crystals, ultra-pure metals, and exotic materials for quantum computing and communication systems. Quantum applications require materials with precisely controlled properties achievable only through sophisticated processing techniques.
Aerospace sector strategic material security encompasses titanium alloys, rare earth permanent magnets, and advanced composites for aircraft and space vehicle manufacturing. Aerospace applications require materials meeting rigorous performance standards for safety and reliability.
Regional Economic Development Opportunities
Industrial Cluster Formation Strategy
Cornwall lithium processing hub development could create integrated supply chains connecting extraction operations with battery manufacturing facilities and research institutions. Regional clusters enable efficiency gains through shared infrastructure, specialised workforce development, and technology innovation.
Wales advanced materials manufacturing zone builds on existing industrial infrastructure to create integrated processing and manufacturing capabilities for critical mineral applications. Regional specialisation enables knowledge concentration and supply chain optimisation.
Scotland renewable energy integration corridor connects mineral processing with offshore wind turbine manufacturing and grid infrastructure development. Integrated development approaches maximise economic benefits and infrastructure efficiency.
Export Market Development for Processed Materials
Value-added mineral product export potential includes processed materials, specialised alloys, and advanced components for international markets. Export development provides revenue diversification and scale economies for domestic processing operations.
Technology licensing opportunities for extraction innovation enable UK companies to monetise technological developments in sustainable extraction methods, advanced processing techniques, and environmental management systems.
Strategic partnership development with allied nations creates opportunities for collaborative processing facilities, joint research programmes, and integrated supply chain development benefiting multiple partner countries.
The UK Critical Minerals Strategy represents a transformative approach to achieving strategic autonomy through domestic resource development and international collaboration. However, success depends on overcoming significant technical, economic, and regulatory challenges while maintaining environmental standards and community support. The implementation of this critical minerals strategy alongside broader mining industry evolution trends will determine whether the UK can achieve its ambitious 2035 targets.
Furthermore, the strategy's effectiveness will depend on coordination with international partners, technological innovation, and sustained political commitment across multiple government cycles. The UK government's comprehensive approach to addressing critical mineral vulnerabilities demonstrates recognition of the strategic importance of these materials, while the detailed strategy document outlines specific implementation mechanisms for achieving mineral independence objectives.
Disclaimer: This analysis is based on available public information and industry projections. Future market conditions, technological developments, and geopolitical factors may significantly impact actual outcomes. Investment decisions should be based on comprehensive due diligence and professional financial advice.
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