한글목차

핵심 자재 회수 시장은 전자 폐기물, 사용된 배터리, 산업 부산물, 사용된 제품 등의 2차 공급원으로부터 귀중한 금속과 미네랄을 추출하는 데 중점을 둔 급속히 확대되고 있는 부문입니다. 이 시장은 공급망의 취약성 증대, 광물 자원을 둘러싼 지정학적 긴장, 전기화가 진행되는 세계 경제의 지속 가능한 물질 흐름에 대한 임박한 요구에 대한 전략적 대응으로 등장했습니다.

이 시장의 주요 성장 촉진요인은 청정 에너지 기술, 전기자동차, 첨단 전자 장비의 핵심 자재에 대한 수요의 가속입니다. 리튬, 코발트, 니켈, 희토류 원소, 백금족 금속, 갈륨 및 인듐과 같은 반도체 재료는 풍력 터빈, 태양전지판, 전기자동차 배터리 및 전자 장비에 필수적입니다. 기존의 채굴은 자원 고갈, 환경 문제, 한 나라에 집중하기 쉬운 공급망 등의 과제에 직면하고 있으며, 2차 회수는 점점 매력적이 되고 있습니다.

현재 시장 예측에 따르면 세계의 핵심 자재 회수 부문은 2046년까지 크게 성장할 전망이며, 그중에서도 리튬 이온 배터리 재활용은 수량과 금액으로 압도적인 점유율을 차지할 것으로 예상되고 있습니다. 시장에는 여러 재료의 흐름이 포함되어 배터리 재활용이 가장 큰 부문이 되고, 희토류 자석 회수, 전자 폐기물로부터의 반도체 재료 추출, 자동차용 촉매로부터의 백금족 금속 회수가 이어집니다.

회수 과정에는 보통 추출과 회수라는 두 가지 주요 단계가 있습니다. 추출 기술에는 습식 야금, 건식 야금, 생물 야금, 이온성 액체 및 초임계 유체 추출과 같은 새로운 접근법이 포함됩니다. 회수 기술에는 용매 추출, 이온 교환, 전해 채취, 침전, 직접 재활용 방법 등이 있습니다. 각 접근법은 효율성, 환경에 미치는 영향, 경제성에 대한 명확한 이점과 도전을 보여줍니다.

습식 야금법은 그 범용성과 건식 야금법에 비해 필요한 에너지가 낮기 때문에 현시점에서 상업 운전의 주류가 되고 있습니다. 그러나 직접 재활용 기술은 특히 배터리 양극 재료와 희토류 자석에서 재료 구조를 유지하고 처리 공정을 줄일 수 있기 때문에 주목 받고 있습니다.

시장은 재료 유형, 공급원 및 회수 방법에 따라 구분할 수 있습니다. 배터리 재활용은 주로 사용한 EV용 배터리 및 소비자 일렉트로닉스용 배터리로부터 리튬, 코발트, 니켈, 망간을 회수하는 데 초점을 맞추었습니다. 희토류 회수는 풍력 터빈과 전기 모터의 영구 자석에서 얻은 네오디뮴, 디스프로슘, 테르븀을 대상으로합니다. 반도체 회수는 전자 폐기물 및 태양광 발전 패널에서 얻은 갈륨, 인듐, 게르마늄, 텔루르를 회수합니다. 백금족 금속 회수는 자동차 촉매 및 신흥 수소 연료전지 응용 분야에 집중하고 있습니다.

경제적 실행 가능성은 재료 유형과 지역에 따라 크게 다릅니다. 백금족 금속이나 희토류와 같은 고가치 재료는 일반적으로 회수의 경제성이 높지만, 리튬과 같은 저가치 재료는 규모와 효율의 개선이 필요합니다. 규제 체제는 특히 유럽, 중국, 북미의 일부에서 재활용 목표와 확대 생산자 책임을 점차 의무화하고 있습니다.

순환경제의 원칙과 공급망의 탄력을 뒷받침하는 정부 정책은 시장의 발전을 가속화하고 있습니다. EU의 Critical Raw Materials Act, 미국의 중요한 광물에 대한 노력, 중국의 재활용 정책은 2차 재료 회수를 지원하는 규제 기세를 창출하고 있습니다.

주요 과제는 회수 인프라 개발, 기술 규모 확대, 1차 생산과의 경제적 경쟁력, 복잡한 폐기물 흐름 처리 등입니다. 많은 중요한 물질은 혼합 폐기물에 저농도로 존재하기 때문에 첨단 분리 기술이 필요하며 회수가 경제적으로 거의 이익이 되지 않는 경우가 많습니다. 2046년을 향한 시장의 궤적은 폐기물의 가용성 증가, 기술적 개선, 정책 지원에 견인된 지속적인 확대를 보여줍니다. 배터리 재활용은 1세대 EV용 배터리가 2030-2035년경에 사용이 끝나면서 극적으로 확대될 것으로 예측됩니다. 희토류 회수는 증가하는 자석 폐기물의 흐름과 공급 안보에 대한 우려로 혜택을 받을 가능성이 높습니다. 이 시장에서 성공하려면 기술 혁신과 경제적 현실의 균형을 맞추면서 2차 핵심 자재 자원의 잠재 능력을 최대한 활용하기 위한 견고한 회수·처리 인프라를 구축할 필요가 있습니다.

본 보고서에서는 세계의 핵심 자재 회수 시장에 대해 조사 분석하고, 리튬 이온 배터리 리사이클, 희토류 원소 회수, 반도체 재료 추출, 백금족 금속 재생에 관한 회수 기술, 시장 예측, 규제 상황, 경쟁 역학 등의 정보를 제공합니다.

목차

제1장 주요 요약

• 핵심 자재의 정의와 중요성
• 핵심 자재원으로서의 전자폐기물
• 전기, 재생에너지, 클린 기술
• 규제 상황
• 주요 시장 성장 촉진요인과 억제요인
• 세계의 핵심 자재 시장(2025년)
• 핵심 자재 추출 기술
• 핵심 자재 밸류체인
• 핵심 자재 회수의 경제 문제
• 핵심 자재 회수의 가격 동향(2020-2024년)
• 세계 시장 예측

제2장 서론

• 핵심 자재
• 공급과 무역의 세계 상황
• 순환경제
• 에너지 전환에 사용되는 중요한 전략적 원재료
• 핵심 자재 회수에 사용하는 기존 및 신흥의 2차 공급원
• 2차 공급원으로부터의 핵심 자재 회수의 비즈니스 모델
• 가공·추출된 금속 및 광물
• 회수원

제3장 반도체에서 중요한 자재 회수

• 중요반도체 재료
• 전자폐기물(e-waste)
• 태양광 발전 기술
• 전자폐기물 중의 중요한 원재료의 농도와 가치
• 핵심 자재의 용도와 중요성
• 폐기물의 재활용 및 회수 프로세스
• 수집·분류 인프라
• 전처리 기술
• 금속 회수 기술
• 세계 시장(2025-2046년)

제4장 리튬 이온 배터리에서 중요한 자재 회수

• 중요 리튬 이온 배터리 금속
• 중요 리튬 이온 배터리 기술의 금속 회수
• 리튬 이온 배터리 리사이클 밸류 체인
• 블랙 머스파우더
• 다른 양극 화학의 재활용
• 준비
• 전처리
• 재활용 기술 비교
• 습식 야금
• 고온 야금
• 직접 재활용
• 기타 방법
• 특정 부품의 재활용
• 리튬 이온 배터리 이외의 재활용
• 리튬 이온 배터리 재활용의 경제 문제
• 경쟁 구도
• 세계의 처리 능력, 현재와 계획 완료
• 미래 전망
• 세계 시장(2025-2046년)

제5장 중요 희토류 원소 회수

• 서론
• 영구자석의 용도
• 회수 기술
• 폐기물로부터 희토류 자석을 재활용하는 기술
• 시장
• 세계 시장(2025-2046년)

제6장 중요 백금족 금속 회수

• 서론
• 공급망
• 가격
• PGM 회수
• 사용한 자동차용 촉매로부터의 PGM 회수
• 수소 전해 장치와 연료전지로부터의 PGM 회수
• 시장
• 세계 시장(2025-2046년)

제7장 기업 프로파일(기업 166개사의 프로파일)

제8장 부록

제9장 참고문헌

영문목차

The critical materials recovery market represents a rapidly expanding sector focused on extracting valuable metals and minerals from secondary sources such as electronic waste, spent batteries, industrial by-products, and end-of-life products. This market has emerged as a strategic response to growing supply chain vulnerabilities, geopolitical tensions surrounding mineral resources, and the urgent need for sustainable material flows in an increasingly electrified global economy.

The market is primarily driven by the accelerating demand for critical materials in clean energy technologies, electric vehicles, and advanced electronics. Lithium, cobalt, nickel, rare earth elements, platinum group metals, and semiconductor materials like gallium and indium have become essential for wind turbines, solar panels, EV batteries, and electronic devices. Traditional mining faces mounting challenges including resource depletion, environmental concerns, and concentrated supply chains often controlled by single countries, making secondary recovery increasingly attractive.

Current market forecasts suggest the global critical materials recovery sector will experience substantial growth through 2046, with lithium-ion battery recycling expected to dominate by volume and value. The market encompasses multiple material streams, with battery recycling representing the largest segment, followed by rare earth magnet recovery, semiconductor material extraction from e-waste, and platinum group metal recovery from automotive catalysts.

The recovery process typically involves two main stages: extraction and recovery. Extraction technologies include hydrometallurgy, pyrometallurgy, biometallurgy, and emerging approaches like ionic liquids and supercritical fluid extraction. Recovery technologies encompass solvent extraction, ion exchange, electrowinning, precipitation, and direct recycling methods. Each approach presents distinct advantages and challenges regarding efficiency, environmental impact, and economic viability.

Hydrometallurgical processes currently dominate commercial operations due to their versatility and lower energy requirements compared to pyrometallurgical methods. However, direct recycling technologies are gaining attention for their potential to preserve material structure and reduce processing steps, particularly for battery cathode materials and rare earth magnets.

The market can be segmented by material type, source, and recovery method. Battery recycling focuses primarily on lithium, cobalt, nickel, and manganese recovery from spent EV and consumer electronics batteries. Rare earth recovery targets neodymium, dysprosium, and terbium from permanent magnets in wind turbines and electric motors. Semiconductor recovery addresses gallium, indium, germanium, and tellurium from electronic waste and photovoltaic panels. Platinum group metal recovery concentrates on automotive catalysts and emerging hydrogen fuel cell applications.

Economic viability varies significantly across material types and regions. High-value materials like platinum group metals and rare earths generally offer better recovery economics, while lower-value materials like lithium require scale and efficiency improvements. Regulatory frameworks increasingly mandate recycling targets and extended producer responsibility, particularly in Europe, China, and parts of North America.

Government policies supporting circular economy principles and supply chain resilience are accelerating market development. The EU's Critical Raw Materials Act, US critical minerals initiatives, and China's recycling policies create regulatory momentum supporting secondary material recovery.

Key challenges include collection infrastructure development, technology scaling, economic competitiveness with primary production, and handling complex waste streams. Many critical materials exist in low concentrations within mixed waste, requiring sophisticated separation technologies and often making recovery economically marginal. The market trajectory toward 2046 suggests continued expansion driven by increasing waste availability, technological improvements, and policy support. Battery recycling is expected to scale dramatically as first-generation EV batteries reach end-of-life around 2030-2035. Rare earth recovery will likely benefit from growing magnet waste streams and supply security concerns. Success in this market requires balancing technological innovation with economic realities, while building robust collection and processing infrastructure to capture the full potential of secondary critical material resources.

"The Global Critical Materials Recovery Market 2026-2046" provides comprehensive analysis of the rapidly expanding critical raw materials recycling industry, driven by supply chain vulnerabilities, electrification trends, and circular economy imperatives. This authoritative report examines recovery technologies, market forecasts, regulatory landscapes, and competitive dynamics across lithium-ion battery recycling, rare earth element recovery, semiconductor material extraction, and platinum group metal reclamation.

Report contents include:

• Definition and strategic importance of critical raw materials in global supply chains
• Electronic waste as emerging source of valuable materials with recovery rate analysis
• Electrification and renewable energy technology material requirements
• Comprehensive regulatory landscape mapping across 11 major countries and global initiatives
• Market drivers, restraints, and growth opportunities through 2046
• Technology readiness evaluation and performance metrics for extraction methods
• Critical materials value chain analysis from collection to refined product delivery
• Economic case studies and price trend analysis for key recovered materials (2020-2024)
• 20-year global market forecasts by material type, recovery source, and region (2026-2046)
• Technology Analysis & Innovation
  • Comprehensive coverage of 17 critical materials including demand trends and applications
  • Primary versus secondary production comparison with environmental impact assessment
  • Advanced extraction technologies: hydrometallurgy, pyrometallurgy, biometallurgy analysis
  • Emerging technologies: ionic liquids, electroleaching, supercritical fluid extraction
  • Recovery methods: solvent extraction, ion exchange, electrowinning, precipitation, biosorption
  • Direct recycling approaches for batteries and rare earth magnets
  • SWOT analysis for each technology category with commercialization readiness assessment
• Market Segments & Applications
  • Semiconductor materials recovery from e-waste and photovoltaic systems
  • Collection infrastructure, pre-processing technologies, and metal recovery processes
  • Lithium-ion battery recycling value chain with cathode chemistry analysis
  • Mechanical, thermal, and chemical pre-treatment methods
  • Hydrometallurgical, pyrometallurgical, and direct recycling process comparison
  • Beyond lithium-ion battery technologies including solid-state and lithium-sulfur systems
  • Rare earth element recovery from permanent magnets and electronic components
  • Long-loop versus short-loop recycling methods with hydrogen decrepitation analysis
  • Platinum group metal recovery from automotive catalysts and fuel cell systems
  • Regional market forecasts with capacity analysis and competitive landscape mapping
• Company Profiles: The report features comprehensive profiles of 166 industry leaders including Accurec Recycling GmbH, ACE Green Recycling, Altilium, American Battery Technology Company (ABTC), Anhua Taisen, Aqua Metals Inc., Ascend Elements, Attero, Australian Strategic Materials Ltd (ASM), BacTech Environmental Corporation, Ballard Power Systems, BANIQL, BASF, Battery Pollution Technologies, Batx Energies Private Limited, Berkeley Energia, BHP, BMW, Botree Cycling, Brazilian Nickel PLC, Carester, Ceibo, Cheetah Resources, CATL, Cirba Solutions, Circunomics, Circu Li-ion, Circular Industries, Cyclic Materials, Cylib, Dowa Eco-System Co., Dow Chemicals, Dundee Sustainable Technologies, DuPont, EcoBat, eCobalt Solutions, EcoGraf, Econili Battery, EcoPro, Ecoprogetti, Electra Battery Materials Corporation (Electra), Electramet, Elmery, Element Zero, Emulsion Flow Technologies, Enim, EnviroMetal Technologies, Eramet, Exigo Recycling, Exitcom Recycling, ExPost Technology, Farasis Energy, First Solar, Fortum Battery Recycling, 4R Energy Corporation, Freeport McMoRan, Fluor, FLSmidth, Ganfeng Lithium, Ganzhou Cyclewell Technology Co. Ltd, Garner Products, GEM Co. Ltd., GLC Recycle Pte. Ltd., Glencore, Gotion, GREEN14, Green Graphite Technologies, Green Li-ion, Green Mineral, GS Group, Guangdong Guanghua Sci-Tech, Huayou Cobalt, Henkel, Heraeus, Huayou Recycling, HydroVolt, HyProMag Ltd, InoBat, Inmetco, Ionic Technologies, Jiecheng New Energy, JL Mag, JPM Silicon GmbH, JX Nippon Metal Mining, Keyking Recycling, Korea Zinc, Kyoei Seiko, Igneo, IXOM, Jervois Global, Jetti Resources, Kemira Oyj, Librec AG, Lithium Australia, LG Chem Ltd., Li-Cycle, Li Industries, Lithion Technologies, Lohum, MagREEsource, Mecaware, Metastable Materials, Metso Corporation, Minerva Lithium, Mining Innovation Rehabilitation and Applied Research (MIRARCO), Mitsubishi Materials, Neometals and more......

TABLE OF CONTENTS

1. EXECUTIVE SUMMARY

• 1.1. Definition and Importance of Critical Raw Materials
• 1.2. E-Waste as a Source of Critical Raw Materials
• 1.3. Electrification, Renewable and Clean Technologies
• 1.4. Regulatory Landscape
  • 1.4.1. European Union
  • 1.4.2. United States
  • 1.4.3. China
  • 1.4.4. Japan
  • 1.4.5. Australia
  • 1.4.6. Canada
  • 1.4.7. India
  • 1.4.8. South Korea
  • 1.4.9. Brazil
  • 1.4.10. Russia
  • 1.4.11. Global Initiatives
• 1.5. Key Market Drivers and Restraints
• 1.6. The Global Critical Raw Materials Market in 2025
• 1.7. Critical Material Extraction Technology
  • 1.7.1. TRL of critical material extraction technologies
  • 1.7.2. Value Proposition
  • 1.7.3. Recovery of critical materials from secondary sources (e.g., end-of-life products, industrial waste)
  • 1.7.4. Critical rare-earth element recovery from secondary sources
  • 1.7.5. Li-ion battery technology metal recovery
  • 1.7.6. Critical semiconductor materials recovery
  • 1.7.7. Critical platinum group metal recovery
  • 1.7.8. Critical platinum Group metal recovery
• 1.8. Critical Raw Materials Value Chain
• 1.9. The Economic Case for Critical Raw Materials Recovery
• 1.10. Price Trends for Key Recovered Materials (2020-2024)
• 1.11. Global market forecasts
  • 1.11.1. By Material Type (2025-2046)
  • 1.11.2. By Recovery Source (2025-2046)
  • 1.11.3. By Region (2025-2046)

2. INTRODUCTION

• 2.1. Critical Raw Materials
• 2.2. Global situation in supply and trade
• 2.3. Circular economy
  • 2.3.1. Circular use of critical raw materials
• 2.4. Critical and strategic raw materials used in the energy transition
  • 2.4.1. Greening critical metals
• 2.5. Established and emerging secondary sources for critical material recovery
• 2.6. Business models for critical material recovery from secondary sources
• 2.7. Metals and minerals processed and extracted
  • 2.7.1. Copper
    • 2.7.1.1. Global copper demand and trends
    • 2.7.1.2. Markets and applications
    • 2.7.1.3. Copper extraction and recovery
  • 2.7.2. Nickel
    • 2.7.2.1. Global nickel demand and trends
    • 2.7.2.2. Markets and applications
    • 2.7.2.3. Nickel extraction and recovery
  • 2.7.3. Cobalt
    • 2.7.3.1. Global cobalt demand and trends
    • 2.7.3.2. Markets and applications
    • 2.7.3.3. Cobalt extraction and recovery
  • 2.7.4. Rare Earth Elements (REE)
    • 2.7.4.1. Global Rare Earth Elements demand and trends
    • 2.7.4.2. Markets and applications
    • 2.7.4.3. Rare Earth Elements extraction and recovery
    • 2.7.4.4. Recovery of REEs from secondary resources
  • 2.7.5. Lithium
    • 2.7.5.1. Global lithium demand and trends
    • 2.7.5.2. Markets and applications
    • 2.7.5.3. Lithium extraction and recovery
  • 2.7.6. Gold
    • 2.7.6.1. Global gold demand and trends
    • 2.7.6.2. Markets and applications
    • 2.7.6.3. Gold extraction and recovery
  • 2.7.7. Uranium
    • 2.7.7.1. Global uranium demand and trends
    • 2.7.7.2. Markets and applications
    • 2.7.7.3. Uranium extraction and recovery
  • 2.7.8. Zinc
    • 2.7.8.1. Global Zinc demand and trends
    • 2.7.8.2. Markets and applications
    • 2.7.8.3. Zinc extraction and recovery
  • 2.7.9. Manganese
    • 2.7.9.1. Global manganese demand and trends
    • 2.7.9.2. Markets and applications
    • 2.7.9.3. Manganese extraction and recovery
  • 2.7.10. Tantalum
    • 2.7.10.1. Global tantalum demand and trends
    • 2.7.10.2. Markets and applications
    • 2.7.10.3. Tantalum extraction and recovery
  • 2.7.11. Niobium
    • 2.7.11.1. Global niobium demand and trends
    • 2.7.11.2. Markets and applications
    • 2.7.11.3. Niobium extraction and recovery
  • 2.7.12. Indium
    • 2.7.12.1. Global indium demand and trends
    • 2.7.12.2. Markets and applications
    • 2.7.12.3. Indium extraction and recovery
  • 2.7.13. Gallium
    • 2.7.13.1. Global gallium demand and trends
    • 2.7.13.2. Markets and applications
    • 2.7.13.3. Gallium extraction and recovery
  • 2.7.14. Germanium
    • 2.7.14.1. Global germanium demand and trends
    • 2.7.14.2. Markets and applications
    • 2.7.14.3. Germanium extraction and recovery
  • 2.7.15. Antimony
    • 2.7.15.1. Global antimony demand and trends
    • 2.7.15.2. Markets and applications
    • 2.7.15.3. Antimony extraction and recovery
  • 2.7.16. Scandium
    • 2.7.16.1. Global scandium demand and trends
    • 2.7.16.2. Markets and applications
    • 2.7.16.3. Scandium extraction and recovery
  • 2.7.17. Graphite
    • 2.7.17.1. Global graphite demand and trends
    • 2.7.17.2. Markets and applications
    • 2.7.17.3. Graphite extraction and recovery
• 2.8. Recovery sources
  • 2.8.1. Primary sources
  • 2.8.2. Secondary sources
    • 2.8.2.1. Extraction
      • 2.8.2.1.1. Hydrometallurgical extraction
        • 2.8.2.1.1.1. Overview
        • 2.8.2.1.1.2. Lixiviants
        • 2.8.2.1.1.3. SWOT analysis
      • 2.8.2.1.2. Pyrometallurgical extraction
        • 2.8.2.1.2.1. Overview
        • 2.8.2.1.2.2. SWOT analysis
      • 2.8.2.1.3. Biometallurgy
        • 2.8.2.1.3.1. Overview
        • 2.8.2.1.3.2. SWOT analysis
      • 2.8.2.1.4. Ionic liquids and deep eutectic solvents
        • 2.8.2.1.4.1. Overview
        • 2.8.2.1.4.2. SWOT analysis
      • 2.8.2.1.5. Electroleaching extraction
        • 2.8.2.1.5.1. Overview
        • 2.8.2.1.5.2. SWOT analysis
      • 2.8.2.1.6. Supercritical fluid extraction
        • 2.8.2.1.6.1. Overview
        • 2.8.2.1.6.2. SWOT analysis
    • 2.8.2.2. Recovery
      • 2.8.2.2.1. Solvent extraction
        • 2.8.2.2.1.1. Overview
        • 2.8.2.2.1.2. Rare-Earth Element Recovery
        • 2.8.2.2.1.3. SWOT analysis
      • 2.8.2.2.2. Ion exchange recovery
        • 2.8.2.2.2.1. Overview
        • 2.8.2.2.2.2. SWOT analysis
      • 2.8.2.2.3. Ionic liquid (IL) and deep eutectic solvent (DES) recovery
        • 2.8.2.2.3.1. Overview
        • 2.8.2.2.3.2. SWOT analysis
      • 2.8.2.2.4. Precipitation
        • 2.8.2.2.4.1. Overview
        • 2.8.2.2.4.2. Coagulation and flocculation
        • 2.8.2.2.4.3. SWOT analysis
      • 2.8.2.2.5. Biosorption
        • 2.8.2.2.5.1. Overview
        • 2.8.2.2.5.2. SWOT analysis
      • 2.8.2.2.6. Electrowinning
        • 2.8.2.2.6.1. Overview
        • 2.8.2.2.6.2. SWOT analysis
      • 2.8.2.2.7. Direct materials recovery
        • 2.8.2.2.7.1. Overview
        • 2.8.2.2.7.2. Rare-earth Oxide (REO) Processing Using Molten Salt Electrolysis
        • 2.8.2.2.7.3. Rare-earth Magnet Recycling by Hydrogen Decrepitation
        • 2.8.2.2.7.4. Direct Recycling of Li-ion Battery Cathodes by Sintering
        • 2.8.2.2.7.5. SWOT analysis

3. CRITICAL RAW MATERIALS RECOVERY IN SEMICONDUCTORS

• 3.1. Critical semiconductor materials
• 3.2. Electronic waste (e-waste)
  • 3.2.1. Types of Critical Raw Materials found in E-Waste
• 3.3. Photovoltaic and solar technologies
  • 3.3.1. Common types of PV panels and their critical semiconductor components
  • 3.3.2. Silicon Recovery Technology for Crystalline-Si PVs
  • 3.3.3. Tellurium Recovery from CdTe Thin-Film Photovoltaics
  • 3.3.4. Solar Panel Manufacturers and Recovery Rates
• 3.4. Concentration and value of Critical Raw Materials in E-Waste
• 3.5. Applications and Importance of Key Critical Raw Materials
• 3.6. Waste Recycling and Recovery Processes
• 3.7. Collection and Sorting Infrastructure
• 3.8. Pre-Processing Technologies
• 3.9. Metal Recovery Technologies
  • 3.9.1. Pyrometallurgy
  • 3.9.2. Hydrometallurgy
  • 3.9.3. Biometallurgy
  • 3.9.4. Supercritical Fluid Extraction
  • 3.9.5. Electrokinetic Separation
  • 3.9.6. Mechanochemical Processing
• 3.10. Global market 2025-2046
  • 3.10.1. Ktonnes
  • 3.10.2. Revenues
  • 3.10.3. Regional

4. CRITICAL RAW MATERIALS RECOVERY IN LI-ION BATTERIES

• 4.1. Critical Li-ion Battery Metals
• 4.2. Critical Li-ion Battery Technology Metal Recovery
• 4.3. Lithium-Ion Battery recycling value chain
• 4.4. Black mass powder
• 4.5. Recycling different cathode chemistries
• 4.6. Preparation
• 4.7. Pre-Treatment
  • 4.7.1. Discharging
  • 4.7.2. Mechanical Pre-Treatment
  • 4.7.3. Thermal Pre-Treatment
• 4.8. Comparison of recycling techniques
• 4.9. Hydrometallurgy
  • 4.9.1. Method overview
    • 4.9.1.1. Solvent extraction
  • 4.9.2. SWOT analysis
• 4.10. Pyrometallurgy
  • 4.10.1. Method overview
  • 4.10.2. SWOT analysis
• 4.11. Direct recycling
  • 4.11.1. Method overview
    • 4.11.1.1. Electrolyte separation
    • 4.11.1.2. Separating cathode and anode materials
    • 4.11.1.3. Binder removal
    • 4.11.1.4. Relithiation
    • 4.11.1.5. Cathode recovery and rejuvenation
    • 4.11.1.6. Hydrometallurgical-direct hybrid recycling
  • 4.11.2. SWOT analysis
• 4.12. Other methods
  • 4.12.1. Mechanochemical Pretreatment
  • 4.12.2. Electrochemical Method
  • 4.12.3. Ionic Liquids
• 4.13. Recycling of Specific Components
  • 4.13.1. Anode (Graphite)
  • 4.13.2. Cathode
  • 4.13.3. Electrolyte
• 4.14. Recycling of Beyond Li-ion Batteries
  • 4.14.1. Conventional vs Emerging Processes
  • 4.14.2. Li-Metal batteries
  • 4.14.3. Lithium sulfur batteries (Li-S)
  • 4.14.4. All-solid-state batteries (ASSBs)
• 4.15. Economic case for Li-ion battery recycling
  • 4.15.1. Metal prices
  • 4.15.2. Second-life energy storage
  • 4.15.3. LFP batteries
  • 4.15.4. Other components and materials
  • 4.15.5. Reducing costs
• 4.16. Competitive landscape
• 4.17. Global capacities, current and planned
• 4.18. Future outlook
• 4.19. Global market 2025-2046
  • 4.19.1. Chemistry
  • 4.19.2. Ktonnes
  • 4.19.3. Revenues
  • 4.19.4. Regional

5. CRITICAL RARE-EARTH ELEMENT RECOVERY

• 5.1. Introduction
• 5.2. Permanent magnet applications
• 5.3. Recovery technologies
  • 5.3.1. Long-loop and short-loop recovery methods
  • 5.3.2. Hydrogen decrepitatio
  • 5.3.3. Powder metallurgy (PM)
  • 5.3.4. Long-loop magnet recycling
  • 5.3.5. Solvent Extraction
  • 5.3.6. Ion Exchange Resin Chromatography
  • 5.3.7. Electrolysis and Metallothermic Reduction
• 5.4. Technologies for recycling rare earth magnets from waste
• 5.5. Markets
  • 5.5.1. Rare-earth magnet market
  • 5.5.2. Rare-earth magnet recovery technology
• 5.6. Global market 2025-2046
  • 5.6.1. Ktonnes
  • 5.6.2. Revenues

6. CRITICAL PLATINUM GROUP METAL RECOVERY

• 6.1. Introduction
• 6.2. Supply chain
• 6.3. Prices
• 6.4. PGM Recovery
• 6.5. PGM recovery from spent automotive catalysts
• 6.6. PGM recovery from hydrogen electrolyzers and fuel cells
  • 6.6.1. Green hydrogen market
  • 6.6.2. PGM recovery from hydrogen-related technologies
  • 6.6.3. Catalyst Coated Membranes (CCMs)
  • 6.6.4. Fuel cell catalysts
  • 6.6.5. Emerging technologies
    • 6.6.5.1. Microwave-assisted Leaching
    • 6.6.5.2. Supercritical Fluid Extraction
    • 6.6.5.3. Bioleaching
    • 6.6.5.4. Electrochemical Recovery
    • 6.6.5.5. Membrane Separation
    • 6.6.5.6. Ionic Liquids
    • 6.6.5.7. Photocatalytic Recovery
  • 6.6.6. Sustainability of the hydrogen economy
• 6.7. Markets
• 6.8. Global market 2025-2046
  • 6.8.1. Ktonnes
  • 6.8.2. Revenues

7. COMPANY PROFILES(166 company profiles)

8. APPENDICES

• 8.1. Research Methodology
• 8.2. Glossary of Terms
• 8.3. List of Abbreviations

9. REFERENCES