세계의 탄소 포집, 활용, 저장(CCUS) 시장(2025-2045년)

Global Carbon Capture, Utilization and Storage (CCUS) Market 2025-2045

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한글목차

전 세계 탄소 포집, 활용, 저장(CCUS) 시장은 국가와 산업계가 넷제로(Net Zero) 목표를 설정함에 따라 그 어느 때보다 빠르게 성장하고 있습니다. 기후 변화 완화를 위한 노력의 증가와 정부의 지원 정책이 성장을 촉진하고 있습니다. 현재 CCUS 시장은 기존 산업 용도와 신기술이 혼재되어 있으며, 포집 용량과 활용 경로가 크게 확대되고 있습니다.

현재 시장은 주로 발전, 시멘트 생산, 수소 생산 등 산업 용도에 초점을 맞춘 점원 탄소 포집가 우세합니다. 주요 산업 기업들은 CCUS 기술을 탈탄소화 전략에 통합하는 추세를 강화하고 있으며, 한편으로는 직접 공기 포집(DAC) 기술의 등장은 탄소 제거 및 활용에 새로운 기회를 가져다주고 있습니다. 벤처 캐피털의 자금 조달이 기록적인 수준에 이르렀고, 기업의 탄소 감축에 대한 약속이 증가함에 따라 시장은 상당한 투자 확대를 보이고 있습니다. 미국의 45Q 세액 공제 및 EU의 Innovation Fund와 같은 이니셔티브를 통한 정부 지원은 CCUS 기술 개발 및 배포에 있어 중국의 급속한 발전은 세계 시장 상황을 재구성하고 있습니다. 현재 상업용 CCUS 시설은 주로 EOR(Enhanced Oil Recovery)에 초점을 맞추고 있지만, 새로운 활용 경로가 확산되고 있습니다. 스타트업들은 저비용 회수 용매, 멤브레인 기술, 모듈형 DAC 시스템에 집중하고 있으며, 마이크로소프트의 클라이?스(Climeworks)의 2억 달러 구매로 대표되는 자발적 탄소 제거 크레딧은 블록체인 기반 추적을 통해 투명성을 높이고, 수익원을 창출하고 있습니다. CO2를 연료, 화학제품, 건축자재로 전환하는 것은 기술 발전과 저탄소 제품에 대한 수요 증가에 힘입어 성장하고 있는 시장 분야입니다.

2045년까지 CCUS 시장은 크게 성장할 것으로 예상됩니다. 규제 요건과 프로젝트 경제성 향상으로 인해 전 세계 포집 용량이 크게 증가할 것으로 예상되며, CCUS와 수소 생산(Blue Hydrogen)의 통합은 배출량 감축이 어려운 산업 부문에서의 활용 확대와 함께 큰 촉진요인이 될 것으로 예상됩니다. 기술 개발은 효율성과 확장성을 향상시키면서 포집 비용을 절감할 것으로 예상됩니다. 재료, 공정 및 통합 전략의 혁신은 특히 직접 공기 포집 및 새로운 활용 경로에서 새로운 시장 기회를 열어줄 것이며, CCUS 허브 및 클러스터의 개발은 인프라 문제를 해결하고 공유 시설을 통해 프로젝트의 경제성을 향상시킬 것으로 예상됩니다.

시장 성장은 탄소 가격 메커니즘의 강화와 전 세계적으로 강화되고 있는 배출 규제에 의해 뒷받침되고 있습니다. 자발적 탄소 시장의 확대는 CCUS 프로젝트에 새로운 수입원을 창출하고 있으며, 기업의 순배출량 제로 약속은 민간 부문의 투자를 촉진하고 있습니다. 그러나 높은 자본 비용, 인프라 요구 사항, 일부 용도에 대한 기술적 장벽 등 CCUS 확산에는 여전히 과제가 남아있습니다. 시장의 성공은 지속적인 정책적 지원, 기술 발전, 지속가능한 비즈니스 모델 개발에 달려있습니다.

세계 탄소 포집, 활용, 저장(CCUS) 시장에 대해 조사 분석했으며, 시장 동향, 기술 개발, 성장 기회에 대한 전략적 인사이트를 제공합니다.

목차

제1장 주요 요약

• 이산화탄소 배출의 주요 발생원
• 상품으로서의 CO2
• 기후 목표 달성
• 시장 촉진요인과 동향
• 현재 시장과 향후 전망
• CCUS 산업의 발전(2020-2025년)
• CCUS 투자
• 정부 CCUS 활동
• 시장 맵
• 상업 CCUS 시설, 프로젝트
• CCUS 밸류체인
• CCUS의 주요 시장 장벽
• 탄소가격제
• 세계 시장 예측

제2장 소개

• CCUS란?
• CO2 운송
• 비용
• 탄소배출권
• CCUS 기술 수명주기 평가(LCA)
• 환경에 대한 영향 평가
• 사회적 수용과 세상 인식

제3장 이산화탄소 포집

• CO2 포집 기술
• 포집율 90% 이상
• 포집율 99%
• 점원에서 CO2 포집
• 주요 탄소 포집 프로세스
• 탄소 분리 기술
• 기회와 장벽
• CO2 포집 비용
• CO2 포집 능력
• 직접공기포집(DAC)
• 하이브리드 포집 시스템
• 탄소 포집의 AI
• 재생에너지 시스템과의 통합
• 모바일 탄소 포집 솔루션
• 탄소 포집 개조

제4장 이산화탄소 제거

• 육상에서의 기존 CDR
• 기술적 CDR 솔루션
• 주요 CDR 방법
• 새로운 CDR 방법
• 기술 성숙도 레벨(TRL) : 이산화탄소 제거 방법
• 탄소배출권
• 탄소배출권 종류
• 밸류체인
• 모니터링, 보고, 검증
• 정부 정책
• 탄소 제거·저장을 갖춘 바이오에너지(BiCRS)
• BECCS
• 강화된 내후성
• 식림/재식림
• 토양 탄소 격리(SCS)
• 바이오차
• 해양 기반 CDR

제5장 이산화탄소 활용

• 개요
• 탄소 활용 비즈니스 모델
• CO2 활용 경로
• 변환 프로세스
• 연료의 CO2 활용
• 화학의 CO2 활용
• 건설·건축자재의 CO2 활용
• 생물학적 수확량 증가의 CO2 활용
• 석유 회수 증진의 CO2 활용
• 강화된 광화 작용
• 탄소 활용의 디지털 솔루션과 IoT
• 탄소 거래의 블록체인 활용
• 데이터센터의 탄소 활용
• 스마트 시티 인프라와의 통합
• 새로운 용도
• CO2 유래 재료를 사용한 3D 프린팅

제6장 이산화탄소 저장

• 소개
• CO2 저장지
• CO2 누출
• 세계의 CO2 저장 용량
• CO2 저장 프로젝트
• CO2-EOR
• 비용
• 과제
• 저장 모니터링 기술
• 지하수소저장 상승효과
• 첨단 모델링과 시뮬레이션
• 저장지 선택 기준
• 리스크 평가와 관리

제7장 이산화탄소 운송

• 소개
• CO2 운송 방법과 조건
• 파이프라인에 의한 CO2 운송
• 선박에 의한 CO2 운송
• 철도와 트럭에 의한 CO2 운송
• 각 방법 비용 분석
• 스마트 파이프라인 네트워크
• 운송 허브와 인프라
• 안전 시스템, 모니터링
• 향후 운송 기술
• 기업

제8장 기업 개요(기업 329개사 프로파일)

제9장 부록

제10장 참고문헌

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영문 목차

영문목차

The global Carbon Capture, Utilization, and Storage (CCUS) market has gained unprecedented momentum as nations and industries align with net-zero goals. is Growth driven by increasing climate change mitigation efforts and supportive government policies. Currently, the market is characterized by a mix of established industrial applications and emerging technologies, with significant expansion in both capture capacity and utilization pathways.

Point source carbon capture dominates the current market, primarily focused on industrial applications including power generation, cement production, and hydrogen manufacturing. Major industrial players are increasingly integrating CCUS technologies into their decarbonization strategies, while the emergence of direct air capture (DAC) technologies is opening new opportunities for carbon removal and utilization. The market is witnessing substantial investment growth, with venture capital funding reaching record levels and increased corporate commitments to carbon reduction. Government support through initiatives like the U.S. 45Q tax credits and the EU's Innovation Fund is accelerating commercial deployment. China's rapid advancement in CCUS technology development and deployment is reshaping the global market landscape. Current commercial CCUS facilities are predominantly focused on enhanced oil recovery (EOR) applications, but new utilization pathways are gaining traction.Start-ups are focusing on low-cost capture solvents, membrane technologies, and modular DAC systems. The voluntary carbon removal credits, exemplified by Microsoft's $200 million purchase from Climeworks, is creating revenue streams, with blockchain-enabled tracking enhancing transparency. The conversion of CO2 into fuels, chemicals, and building materials represents growing market segments, supported by technological advances and increasing demand for low-carbon products.

Looking toward 2045, the CCUS market is expected to expand significantly. Projections indicate a substantial increase in global capture capacity, driven by both regulatory requirements and improving project economics. The integration of CCUS with hydrogen production (blue hydrogen) is expected to be a major growth driver, alongside expanding applications in hard-to-abate industrial sectors. Technological developments are expected to reduce capture costs while improving efficiency and scalability. Innovation in materials, processes, and integration strategies is likely to open new market opportunities, particularly in direct air capture and novel utilization pathways. The development of CCUS hubs and clusters is anticipated to solve infrastructure challenges and improve project economics through shared facilities.

Market growth is supported by strengthening carbon pricing mechanisms and increasingly stringent emissions regulations globally. The voluntary carbon market's expansion is creating additional revenue streams for CCUS projects, while corporate net-zero commitments are driving private sector investment. However, challenges remain in scaling up CCUS deployment, including high capital costs, infrastructure requirements, and technical barriers in some applications. The success of the market will depend on continued policy support, technology advancement, and the development of sustainable business models.

"The Global Carbon Capture, Utilization and Storage (CCUS) Market 2025-2045" report provides a detailed analysis of the global Carbon Capture, Utilization and Storage (CCUS) sector, offering strategic insights into market trends, technology developments, and growth opportunities from 2025 to 2045. The study examines the entire CCUS value chain, from capture technologies to end-use applications and storage solutions. The report delivers in-depth analysis of CCUS technologies, market dynamics, and competitive landscapes across key segments including direct air capture (DAC), point source capture, utilization pathways, and storage solutions. It provides detailed market forecasts, technology assessments, and competitive analysis, supported by extensive primary research and industry expertise.

Contents include:

• Key Market Segments:
  • Carbon Capture Technologies (post-combustion, pre-combustion, oxy-fuel)
  • Utilization Pathways (fuels, chemicals, building materials, EOR)
  • Storage Solutions (geological storage, mineralization)
  • Direct Air Capture Technologies
  • Transportation Infrastructure
  • End-use Applications
• Comprehensive coverage of CCUS technologies including:
  • Advanced capture materials and processes
  • Novel separation technologies
  • Utilization pathways and conversion processes
  • Storage monitoring and verification systems
  • Integration with renewable energy systems
  • Artificial intelligence and digital solutions
• Detailed market metrics including:
  • Global revenue projections (2025-2035)
  • Regional market analysis
  • Technology adoption rates
  • Cost trends and projections
  • Investment landscape
  • Policy and regulatory frameworks
• Special Focus Areas including:
  • Blue hydrogen production
  • Cement sector applications
  • Maritime carbon capture
  • Direct air capture technologies
  • Biological carbon removal
  • Enhanced oil recovery
  • Construction materials
• Strategic Insights including:
  • Market opportunities and growth drivers
  • Technology roadmaps
  • Investment trends
  • Regional market dynamics
  • Policy impacts
  • Project economics
• Applications and End Markets:
  • Power generation
  • Industrial processes
  • Chemical production
  • Building materials
  • Fuel synthesis
  • Agriculture and food production
  • Environmental remediation
• Regulatory and Policy Analysis:
  • Carbon pricing mechanisms
  • Government initiatives
  • Tax credits and incentives
  • Environmental regulations
  • International agreements
  • Market mechanisms
• Project Analysis:
  • Operational facilities
  • Projects under development
  • Cost analysis
  • Performance metrics
  • Success factors
  • Case studies
• Market Drivers and Challenges:
  • Analysis of over 300 companies across the CCUS value chain, including:
    • Technology developers
    • Project developers
    • Industrial users
    • Oil and gas companies
    • Chemical manufacturers
    • Service providers

Companies profiled include: 1point8, 3R-BioPhosphate, 44.01, 8Rivers, Adaptavate, ADNOC, Aeroborn B.V., Aether Diamonds, Again, Air Company, Air Liquide S.A., Air Products and Chemicals Inc., Air Protein, Air Quality Solutions Worldwide DAC, Airca Process Technology, Aircela Inc, AirCapture LLC, Airex Energy, AirHive, Airovation Technologies, Algal Bio Co. Ltd., Algiecel ApS, Algenol, Andes Ag Inc., Aqualung Carbon Capture, Arborea, Arca, Arkeon Biotechnologies, Asahi Kasei, AspiraDAC Pty Ltd., Aspiring Materials, Atoco, Avantium N.V., Avnos Inc., Axens SA, Aymium, Azolla, BASF Group, Barton Blakeley Technologies Ltd., BC Biocarbon, Blue Planet Systems Corporation, BluSky Inc., BP PLC, Breathe Applied Sciences, Bright Renewables, Brilliant Planet, bse Methanol GmbH, C-Capture, C2CNT LLC, C4X Technologies Inc., Cambridge Carbon Capture Ltd., Capchar Ltd., Captura Corporation, Capture6, Carba, CarbiCrete, Carbfix, Carboclave, Carbo Culture, Carbon Blade, Carbon Blue, Carbon CANTONNE, Carbon Capture Inc., Carbon Capture Machine (UK), Carbon Centric AS, Carbon Clean Solutions Limited, Carbon Collect Limited, Carbon Engineering Ltd., Carbon Geocapture Corp, Carbon Infinity Limited, Carbon Limit, Carbon Neutral Fuels, Carbon Re, Carbon Recycling International, Carbon Reform Inc., Carbon Ridge Inc., Carbon Sink LLC, Carbon Upcycling Technologies, Carbon-Zero US LLC, Carbon8 Systems, CarbonBuilt, CarbonCure Technologies Inc., Carbonfex Oy, CarbonFree, Carbonfree Chemicals, Carbonade, Carbonaide Oy, Carbonaught Pty Ltd., CarbonMeta Research Ltd., Carbominer, CarbonOrO Products B.V., CarbonQuest, CarbonScape Ltd., CarbonStar Systems, Carbyon BV, Cella Mineral Storage, Cemvita Factory Inc., CERT Systems Inc., CFOAM Limited, Charm Industrial, Chevron Corporation, China Energy Investment Corporation (CHN Energy), Chiyoda Corporation, Climeworks, CNF Biofuel AS, CO2 Capsol, CO2CirculAir B.V., CO2Rail Company, Compact Carbon Capture AS (Baker Hughes), Concrete4Change, Coval Energy B.V., Covestro AG, C-Quester Inc., Cquestr8 Limited, CyanoCapture, D-CRBN, Decarbontek LLC, Deep Branch Biotechnology, Deep Sky, Denbury Inc., Dimensional Energy, Dioxide Materials, Dioxycle, Earth RepAIR, Ebb Carbon, Ecocera, EcoClosure LLC, ecoLocked GmbH, Econic Technologies Ltd., Eion Carbon, Electrochaea GmbH, Emerging Fuels Technology (EFT), Empower Materials Inc., enaDyne GmbH, Enerkem Inc., Entropy Inc., E-Quester, Equatic, Equinor ASA, Evonik Industries AG, Exomad Green, ExxonMobil, Fairbrics, Fervo Energy, Fluor Corporation, Fortera Corporation, Framergy Inc., FuelCell Energy Inc., Funga, GE Gas Power (General Electric), Giammarco Vetrocoke, Giner Inc., Global Algae Innovations, Global Thermostat LLC, Graphyte, Graviky Labs, GreenCap Solutions AS, Greeniron H2 AB, Greenlyte Carbon Technologies, Green Sequest, greenSand, Gulf Coast Sequestration, Hago Energetics, Haldor Topsoe, Heimdal CCU, Heirloom Carbon Technologies, High Hopes Labs, Holcene, Holcim Group, Holy Grail Inc., Honeywell, IHI Corporation, Immaterial Ltd., Ineratec GmbH, Infinitree LLC, Innovator Energy, InnoSepra LLC, Inplanet GmbH, InterEarth, ION Clean Energy Inc., Japan CCS Co. Ltd., Jupiter Oxygen Corporation, Kawasaki Heavy Industries Ltd., KC8 Capture Technologies, Krajete GmbH, LanzaJet Inc., Lanzatech, Lectrolyst LLC, Levidian Nanosystems, The Linde Group, Liquid Wind AB, Lithos Carbon, Living Carbon, Loam Bio, Low Carbon Korea and more.

TABLE OF CONTENTS

1. EXECUTIVE SUMMARY

• 1.1. Main sources of carbon dioxide emissions
• 1.2. CO2 as a commodity
• 1.3. Meeting climate targets
• 1.4. Market drivers and trends
• 1.5. The current market and future outlook
• 1.6. CCUS Industry developments 2020-2025
• 1.7. CCUS investments
  • 1.7.1. Venture Capital Funding
    • 1.7.1.1. 2010-2024
    • 1.7.1.2. CCUS VC deals 2022-2025
• 1.8. Government CCUS initiatives
  • 1.8.1. North America
  • 1.8.2. Europe
  • 1.8.3. Asia
    • 1.8.3.1. Japan
    • 1.8.3.2. Singapore
    • 1.8.3.3. China
• 1.9. Market map
• 1.10. Commercial CCUS facilities and projects
  • 1.10.1. Facilities
    • 1.10.1.1. Operational
    • 1.10.1.2. Under development/construction
• 1.11. CCUS Value Chain
• 1.12. Key market barriers for CCUS
• 1.13. Carbon pricing
  • 1.13.1. Compliance Carbon Pricing Mechanisms
  • 1.13.2. Alternative to Carbon Pricing: 45Q Tax Credits
  • 1.13.3. Business models
  • 1.13.4. The European Union Emission Trading Scheme (EU ETS)
  • 1.13.5. Carbon Pricing in the US
  • 1.13.6. Carbon Pricing in China
  • 1.13.7. Voluntary Carbon Markets
  • 1.13.8. Challenges with Carbon Pricing
• 1.14. Global market forecasts
  • 1.14.1. CCUS capture capacity forecast by end point
  • 1.14.2. Capture capacity by region to 2045, Mtpa
  • 1.14.3. Revenues
  • 1.14.4. CCUS capacity forecast by capture type
  • 1.14.5. Cost projections 2025-2045

2. INTRODUCTION

• 2.1. What is CCUS?
  • 2.1.1. Carbon Capture
    • 2.1.1.1. Source Characterization
    • 2.1.1.2. Purification
    • 2.1.1.3. CO2 capture technologies
  • 2.1.2. Carbon Utilization
    • 2.1.2.1. CO2 utilization pathways
  • 2.1.3. Carbon storage
    • 2.1.3.1. Passive storage
    • 2.1.3.2. Enhanced oil recovery
• 2.2. Transporting CO2
  • 2.2.1. Methods of CO2 transport
    • 2.2.1.1. Pipeline
    • 2.2.1.2. Ship
    • 2.2.1.3. Road
    • 2.2.1.4. Rail
  • 2.2.2. Safety
• 2.3. Costs
  • 2.3.1. Cost of CO2 transport
• 2.4. Carbon credits
• 2.5. Life Cycle Assessment (LCA) of CCUS Technologies
• 2.6. Environmental Impact Assessment
• 2.7. Social acceptance and public perception

3. CARBON DIOXIDE CAPTURE

• 3.1. CO2 capture technologies
• 3.2. >90% capture rate
• 3.3. 99% capture rate
• 3.4. CO2 capture from point sources
  • 3.4.1. Energy Availability and Costs
  • 3.4.2. Power plants with CCUS
  • 3.4.3. Transportation
  • 3.4.4. Global point source CO2 capture capacities
  • 3.4.5. By source
  • 3.4.6. Blue hydrogen
    • 3.4.6.1. Steam-methane reforming (SMR)
    • 3.4.6.2. Autothermal reforming (ATR)
    • 3.4.6.3. Partial oxidation (POX)
    • 3.4.6.4. Sorption Enhanced Steam Methane Reforming (SE-SMR)
    • 3.4.6.5. Pre-Combustion vs. Post-Combustion carbon capture
    • 3.4.6.6. Blue hydrogen projects
    • 3.4.6.7. Costs
    • 3.4.6.8. Market players
  • 3.4.7. Carbon capture in cement
    • 3.4.7.1. CCUS Projects
    • 3.4.7.2. Carbon capture technologies
    • 3.4.7.3. Costs
    • 3.4.7.4. Challenges
  • 3.4.8. Maritime carbon capture
• 3.5. Main carbon capture processes
  • 3.5.1. Materials
  • 3.5.2. Post-combustion
    • 3.5.2.1. Chemicals/Solvents
    • 3.5.2.2. Amine-based post-combustion CO2 absorption
    • 3.5.2.3. Physical absorption solvents
  • 3.5.3. Oxy-fuel combustion
    • 3.5.3.1. Oxyfuel CCUS cement projects
    • 3.5.3.2. Chemical Looping-Based Capture
  • 3.5.4. Liquid or supercritical CO2: Allam-Fetvedt Cycle
  • 3.5.5. Pre-combustion
• 3.6. Carbon separation technologies
  • 3.6.1. Absorption capture
  • 3.6.2. Adsorption capture
    • 3.6.2.1. Solid sorbent-based CO2 separation
    • 3.6.2.2. Metal organic framework (MOF) adsorbents
    • 3.6.2.3. Zeolite-based adsorbents
    • 3.6.2.4. Solid amine-based adsorbents
    • 3.6.2.5. Carbon-based adsorbents
    • 3.6.2.6. Polymer-based adsorbents
    • 3.6.2.7. Solid sorbents in pre-combustion
    • 3.6.2.8. Sorption Enhanced Water Gas Shift (SEWGS)
    • 3.6.2.9. Solid sorbents in post-combustion
  • 3.6.3. Membranes
    • 3.6.3.1. Membrane-based CO2 separation
    • 3.6.3.2. Post-combustion CO2 capture
      • 3.6.3.2.1. Facilitated transport membranes
    • 3.6.3.3. Pre-combustion capture
  • 3.6.4. Liquid or supercritical CO2 (Cryogenic) capture
    • 3.6.4.1. Cryogenic CO2 capture
  • 3.6.5. Calcium Looping
    • 3.6.5.1. Calix Advanced Calciner
  • 3.6.6. Other technologies
    • 3.6.6.1. LEILAC process
    • 3.6.6.2. CO2 capture with Solid Oxide Fuel Cells (SOFCs)
    • 3.6.6.3. CO2 capture with Molten Carbonate Fuel Cells (MCFCs)
    • 3.6.6.4. Microalgae Carbon Capture
  • 3.6.7. Comparison of key separation technologies
  • 3.6.8. Technology readiness level (TRL) of gas separation technologies
• 3.7. Opportunities and barriers
• 3.8. Costs of CO2 capture
• 3.9. CO2 capture capacity
• 3.10. Direct air capture (DAC)
  • 3.10.1. Technology description
    • 3.10.1.1. Sorbent-based CO2 Capture
    • 3.10.1.2. Solvent-based CO2 Capture
    • 3.10.1.3. DAC Solid Sorbent Swing Adsorption Processes
    • 3.10.1.4. Electro-Swing Adsorption (ESA) of CO2 for DAC
    • 3.10.1.5. Solid and liquid DAC
  • 3.10.2. Advantages of DAC
  • 3.10.3. Deployment
  • 3.10.4. Point source carbon capture versus Direct Air Capture
  • 3.10.5. Technologies
    • 3.10.5.1. Solid sorbents
    • 3.10.5.2. Liquid sorbents
    • 3.10.5.3. Liquid solvents
    • 3.10.5.4. Airflow equipment integration
    • 3.10.5.5. Passive Direct Air Capture (PDAC)
    • 3.10.5.6. Direct conversion
    • 3.10.5.7. Co-product generation
    • 3.10.5.8. Low Temperature DAC
    • 3.10.5.9. Regeneration methods
  • 3.10.6. Electricity and Heat Sources
  • 3.10.7. Commercialization and plants
  • 3.10.8. Metal-organic frameworks (MOFs) in DAC
  • 3.10.9. DAC plants and projects-current and planned
  • 3.10.10. Capacity forecasts
  • 3.10.11. Costs
  • 3.10.12. Market challenges for DAC
  • 3.10.13. Market prospects for direct air capture
  • 3.10.14. Players and production
  • 3.10.15. Co2 utilization pathways
  • 3.10.16. Markets for Direct Air Capture and Storage (DACCS)
    • 3.10.16.1. Fuels
      • 3.10.16.1.1. Overview
      • 3.10.16.1.2. Production routes
      • 3.10.16.1.3. Methanol
      • 3.10.16.1.4. Algae based biofuels
      • 3.10.16.1.5. CO2-fuels from solar
      • 3.10.16.1.6. Companies
      • 3.10.16.1.7. Challenges
    • 3.10.16.2. Chemicals, plastics and polymers
      • 3.10.16.2.1. Overview
      • 3.10.16.2.2. Scalability
      • 3.10.16.2.3. Plastics and polymers
        • 3.10.16.2.3.1. CO2 utilization products
      • 3.10.16.2.4. Urea production
      • 3.10.16.2.5. Inert gas in semiconductor manufacturing
      • 3.10.16.2.6. Carbon nanotubes
      • 3.10.16.2.7. Companies
    • 3.10.16.3. Construction materials
      • 3.10.16.3.1. Overview
      • 3.10.16.3.2. CCUS technologies
      • 3.10.16.3.3. Carbonated aggregates
      • 3.10.16.3.4. Additives during mixing
      • 3.10.16.3.5. Concrete curing
      • 3.10.16.3.6. Costs
      • 3.10.16.3.7. Companies
      • 3.10.16.3.8. Challenges
    • 3.10.16.4. CO2 Utilization in Biological Yield-Boosting
      • 3.10.16.4.1. Overview
      • 3.10.16.4.2. Applications
        • 3.10.16.4.2.1. Greenhouses
        • 3.10.16.4.2.2. Algae cultivation
        • 3.10.16.4.2.3. Microbial conversion
      • 3.10.16.4.3. Companies
    • 3.10.16.5. Food and feed production
    • 3.10.16.6. CO2 Utilization in Enhanced Oil Recovery
      • 3.10.16.6.1. Overview
        • 3.10.16.6.1.1. Process
        • 3.10.16.6.1.2. CO2 sources
      • 3.10.16.6.2. CO2-EOR facilities and projects
• 3.11. Hybrid Capture Systems
• 3.12. Artificial Intelligence in Carbon Capture
• 3.13. Integration with Renewable Energy Systems
• 3.14. Mobile Carbon Capture Solutions
• 3.15. Carbon Capture Retrofitting

4. CARBON DIOXIDE REMOVAL

• 4.1. Conventional CDR on land
  • 4.1.1. Wetland and peatland restoration
  • 4.1.2. Cropland, grassland, and agroforestry
• 4.2. Technological CDR Solutions
• 4.3. Main CDR methods
• 4.4. Novel CDR methods
• 4.5. Technology Readiness Level (TRL): Carbon Dioxide Removal Methods
• 4.6. Carbon Credits
  • 4.6.1. CO2 Utilization
  • 4.6.2. Biochar and Agricultural Products
  • 4.6.3. Renewable Energy Generation
  • 4.6.4. Ecosystem Services
• 4.7. Types of Carbon Credits
  • 4.7.1. Voluntary Carbon Credits
  • 4.7.2. Compliance Carbon Credits
  • 4.7.3. Corporate commitments
  • 4.7.4. Increasing government support and regulations
  • 4.7.5. Advancements in carbon offset project verification and monitoring
  • 4.7.6. Potential for blockchain technology in carbon credit trading
  • 4.7.7. Prices
  • 4.7.8. Buying and Selling Carbon Credits
    • 4.7.8.1. Carbon credit exchanges and trading platforms
    • 4.7.8.2. Over-the-counter (OTC) transactions
    • 4.7.8.3. Pricing mechanisms and factors affecting carbon credit prices
  • 4.7.9. Certification
  • 4.7.10. Challenges and risks
• 4.8. Value chain
• 4.9. Monitoring, reporting, and verification
• 4.10. Government policies
• 4.11. Bioenergy with Carbon Removal and Storage (BiCRS)
  • 4.11.1. Advantages
  • 4.11.2. Challenges
  • 4.11.3. Costs
  • 4.11.4. Feedstocks
• 4.12. BECCS
  • 4.12.1. Technology overview
    • 4.12.1.1. Point Source Capture Technologies for BECCS
    • 4.12.1.2. Energy efficiency
    • 4.12.1.3. Heat generation
    • 4.12.1.4. Waste-to-Energy
    • 4.12.1.5. Blue Hydrogen Production
  • 4.12.2. Biomass conversion
  • 4.12.3. CO2 capture technologies
  • 4.12.4. BECCS facilities
  • 4.12.5. Cost analysis
  • 4.12.6. BECCS carbon credits
  • 4.12.7. Sustainability
  • 4.12.8. Challenges
• 4.13. Enhanced Weathering
  • 4.13.1. Overview
    • 4.13.1.1. Role of enhanced weathering in carbon dioxide removal
    • 4.13.1.2. CO2 mineralization
  • 4.13.2. Enhanced Weathering Processes and Materials
  • 4.13.3. Enhanced Weathering Applications
  • 4.13.4. Trends and Opportunities
  • 4.13.5. Challenges and Risks
  • 4.13.6. Cost analysis
  • 4.13.7. SWOT analysis
• 4.14. Afforestation/Reforestation
  • 4.14.1. Overview
  • 4.14.2. Carbon dioxide removal methods
  • 4.14.3. Projects
  • 4.14.4. Remote sensing in A/R
  • 4.14.5. Robotics
  • 4.14.6. Trends and Opportunities
  • 4.14.7. Challenges and Risks
  • 4.14.8. SWOT analysis
• 4.15. Soil carbon sequestration (SCS)
  • 4.15.1. Overview
  • 4.15.2. Practices
  • 4.15.3. Measuring and Verifying
  • 4.15.4. Trends and Opportunities
  • 4.15.5. Carbon credits
  • 4.15.6. Challenges and Risks
  • 4.15.7. SWOT analysis
• 4.16. Biochar
  • 4.16.1. What is biochar?
  • 4.16.2. Carbon sequestration
  • 4.16.3. Properties of biochar
  • 4.16.4. Feedstocks
  • 4.16.5. Production processes
    • 4.16.5.1. Sustainable production
    • 4.16.5.2. Pyrolysis
      • 4.16.5.2.1. Slow pyrolysis
      • 4.16.5.2.2. Fast pyrolysis
    • 4.16.5.3. Gasification
    • 4.16.5.4. Hydrothermal carbonization (HTC)
    • 4.16.5.5. Torrefaction
    • 4.16.5.6. Equipment manufacturers
  • 4.16.6. Biochar pricing
  • 4.16.7. Biochar carbon credits
    • 4.16.7.1. Overview
    • 4.16.7.2. Removal and reduction credits
    • 4.16.7.3. The advantage of biochar
    • 4.16.7.4. Prices
    • 4.16.7.5. Buyers of biochar credits
    • 4.16.7.6. Competitive materials and technologies
  • 4.16.8. Bio-oil based CDR
  • 4.16.9. Biomass burial for CO2 removal
  • 4.16.10. Bio-based construction materials for CDR
  • 4.16.11. SWOT analysis
• 4.17. Ocean-based CDR
  • 4.17.1. Overview
  • 4.17.2. Ocean pumps
  • 4.17.3. CO2 capture from seawater
  • 4.17.4. Ocean fertilisation
  • 4.17.5. Coastal blue carbon
  • 4.17.6. Algal cultivation
  • 4.17.7. Artificial upwelling
  • 4.17.8. MRV for marine CDR
  • 4.17.9. Ocean alkalinisation
  • 4.17.10. Ocean alkalinity enhancement (OAE)
  • 4.17.11. Electrochemical ocean alkalinity enhancement
  • 4.17.12. Direct ocean capture technology
  • 4.17.13. Artificial downwelling
  • 4.17.14. Trends and Opportunities
  • 4.17.15. Ocean-based carbon credits
  • 4.17.16. Cost analysis
  • 4.17.17. Challenges and Risks
  • 4.17.18. SWOT analysis

5. CARBON DIOXIDE UTILIZATION

• 5.1. Overview
  • 5.1.1. Current market status
• 5.2. Carbon utilization business models
  • 5.2.1. Benefits of carbon utilization
  • 5.2.2. Market challenges
• 5.3. Co2 utilization pathways
• 5.4. Conversion processes
  • 5.4.1. Thermochemical
    • 5.4.1.1. Process overview
    • 5.4.1.2. Plasma-assisted CO2 conversion
  • 5.4.2. Electrochemical conversion of CO2
    • 5.4.2.1. Process overview
  • 5.4.3. Photocatalytic and photothermal catalytic conversion of CO2
  • 5.4.4. Catalytic conversion of CO2
  • 5.4.5. Biological conversion of CO2
  • 5.4.6. Copolymerization of CO2
  • 5.4.7. Mineral carbonation
• 5.5. CO2-Utilization in Fuels
  • 5.5.1. Overview
  • 5.5.2. Production routes
  • 5.5.3. CO2 -fuels in road vehicles
  • 5.5.4. CO2 -fuels in shipping
  • 5.5.5. CO2 -fuels in aviation
  • 5.5.6. Costs of e-fuel
  • 5.5.7. Power-to-methane
    • 5.5.7.1. Thermocatalytic pathway to e-methane
    • 5.5.7.2. Biological fermentation
    • 5.5.7.3. Costs
  • 5.5.8. Algae based biofuels
  • 5.5.9. DAC for e-fuels
  • 5.5.10. Syngas Production Options
  • 5.5.11. CO2-fuels from solar
  • 5.5.12. Companies
  • 5.5.13. Challenges
  • 5.5.14. Global market forecasts 2025-2045
• 5.6. CO2-Utilization in Chemicals
  • 5.6.1. Overview
  • 5.6.2. Carbon nanostructures
  • 5.6.3. Scalability
  • 5.6.4. Pathways
    • 5.6.4.1. Thermochemical
    • 5.6.4.2. Electrochemical
      • 5.6.4.2.1. Low-Temperature Electrochemical CO2 Reduction
      • 5.6.4.2.2. High-Temperature Solid Oxide Electrolyzers
      • 5.6.4.2.3. Coupling H2 and Electrochemical CO2 Reduction
    • 5.6.4.3. Microbial conversion
    • 5.6.4.4. Other
      • 5.6.4.4.1. Photocatalytic
      • 5.6.4.4.2. Plasma technology
  • 5.6.5. Applications
    • 5.6.5.1. Urea production
    • 5.6.5.2. CO2-derived polymers
      • 5.6.5.2.1. Pathways
      • 5.6.5.2.2. Polycarbonate from CO2
      • 5.6.5.2.3. Methanol to olefins (polypropylene production)
      • 5.6.5.2.4. Ethanol to polymers
    • 5.6.5.3. Inert gas in semiconductor manufacturing
  • 5.6.6. Companies
  • 5.6.7. Global market forecasts 2025-2045
• 5.7. CO2-Utilization in Construction and Building Materials
  • 5.7.1. Overview
  • 5.7.2. Market drivers
  • 5.7.3. Key CO2 utilization technologies in construction
  • 5.7.4. Carbonated aggregates
  • 5.7.5. Additives during mixing
  • 5.7.6. Concrete curing
  • 5.7.7. Costs
  • 5.7.8. Market trends and business models
  • 5.7.9. Carbon credits
  • 5.7.10. Companies
  • 5.7.11. Challenges
  • 5.7.12. Global market forecasts
• 5.8. CO2-Utilization in Biological Yield-Boosting
  • 5.8.1. Overview
  • 5.8.2. CO2 utilization in biological processes
  • 5.8.3. Applications
    • 5.8.3.1. Greenhouses
      • 5.8.3.1.1. CO2 enrichment
    • 5.8.3.2. Algae cultivation
      • 5.8.3.2.1. CO2-enhanced algae cultivation: open systems
      • 5.8.3.2.2. CO2-enhanced algae cultivation: closed systems
    • 5.8.3.3. Microbial conversion
    • 5.8.3.4. Food and feed production
  • 5.8.4. Companies
  • 5.8.5. Global market forecasts 2025-2045
• 5.9. CO2 Utilization in Enhanced Oil Recovery
  • 5.9.1. Overview
    • 5.9.1.1. Process
    • 5.9.1.2. CO2 sources
  • 5.9.2. CO2-EOR facilities and projects
  • 5.9.3. Challenges
  • 5.9.4. Global market forecasts 2025-2045
• 5.10. Enhanced mineralization
  • 5.10.1. Advantages
  • 5.10.2. In situ and ex-situ mineralization
  • 5.10.3. Enhanced mineralization pathways
  • 5.10.4. Challenges
• 5.11. Digital Solutions and IoT in Carbon Utilization
• 5.12. Blockchain Applications in Carbon Trading
• 5.13. Carbon Utilization in Data Centers
• 5.14. Integration with Smart City Infrastructure
• 5.15. Novel Applications
• 5.15.1 3D Printing with CO2-derived Materials
  • 5.15.2. CO2 in Energy Storage
  • 5.15.3. CO2 in Electronics Manufacturing

6. CARBON DIOXIDE STORAGE

• 6.1. Introduction
• 6.2. CO2 storage sites
  • 6.2.1. Storage types for geologic CO2 storage
  • 6.2.2. Oil and gas fields
  • 6.2.3. Saline formations
  • 6.2.4. Coal seams and shale
  • 6.2.5. Basalts and ultra-mafic rocks
• 6.3. CO2 leakage
• 6.4. Global CO2 storage capacity
• 6.5. CO2 Storage Projects
• 6.6. CO2 -EOR
  • 6.6.1. Description
  • 6.6.2. Injected CO2
  • 6.6.3. CO2 capture with CO2 -EOR facilities
  • 6.6.4. Companies
  • 6.6.5. Economics
• 6.7. Costs
• 6.8. Challenges
• 6.9. Storage Monitoring Technologies
• 6.10. Underground Hydrogen Storage Synergies
• 6.11. Advanced Modelling and Simulation
• 6.12. Storage Site Selection Criteria
• 6.13. Risk Assessment and Management

7. CARBON DIOXIDE TRANSPORTATION

• 7.1. Introduction
• 7.2. CO2 transportation methods and conditions
• 7.3. CO2 transportation by pipeline
• 7.4. CO2 transportation by ship
• 7.5. CO2 transportation by rail and truck
• 7.6. Cost analysis of different methods
• 7.7. Smart Pipeline Networks
• 7.8. Transportation Hubs and Infrastructure
• 7.9. Safety Systems and Monitoring
• 7.10. Future Transportation Technologies
• 7.11. Companies

8. COMPANY PROFILES(329 company profiles)

9. APPENDICES

• 9.1. Abbreviations
• 9.2. Research Methodology
• 9.3. Definition of Carbon Capture, Utilisation and Storage (CCUS)
• 9.4. Technology Readiness Level (TRL)

10. REFERENCES

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