Dublin–(Business Wire)–Global Carbon Capture, Utilization and Storage Technologies Market report added to ResearchAndMarkets.com’s supply.
The market for CO2 use is expected to remain relatively small (<$2.5 billion) in the short term, but to grow over the next few years, driven by reductions in industrial carbon emissions.
Carbon capture, utilization and storage (CCUS) refers to technologies that capture CO2 emissions and use or store them for permanent storage. CCUS technology captures carbon dioxide emissions from large energy sources, including power generation or industrial facilities that use fossil fuels or biomass as fuel.
CO2 can also be captured directly from the atmosphere. If not used on site, the captured CO2 is compressed and transported by pipeline, ship, rail or truck for a range of applications, or injected into deep geological formations (including depleted oil and gas reservoirs or saline formations) that capture the CO2 for permanent storage.
Carbon removal technologies include direct air capture (DAC) or bioenergy with carbon capture and storage (BECCS). This rapidly growing market is driven by government climate initiatives and increasing public and private investments. Private investment in CCUS companies has surpassed $1 billion through 2022.
New ways to use CO2 in the production of fuels, chemicals and building materials are driving global attention and growing support from governments, industry and investors. Climeworks, a Swiss startup developing direct air capture (DAC), raised $650 million in funding in April 2022.
The report content includes:
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Global Market Analysis for Carbon Capture, Utilization and Storage (CCUS) Technologies.
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Carbon Capture, Utilization and Storage (CCUS) Market Developments, Funding and Investments 2020-2022.
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Analysis of key market dynamics, trends, opportunities and factors impacting the global Carbon, Capture Utilization and Storage Technologies market and its sub-segments.
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Market barriers for carbon capture, utilization and storage (CCUS) technologies.
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Market analysis of CO2-derived products including fuels, chemicals, mineral construction materials, waste construction materials, enhanced oil recovery, and CO2 use for enhanced bioprocess production.
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Market Value and Forecast to 2040.
Profiles of 191 carbon capture, utilization and storage (CCUS) companies, including products, partnerships and investment funding.
Companies introduced include
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algae cell
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Cambridge Carbon Capture
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Carbon Engineering Ltd
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capture
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Cabin BV
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CarbonCure Technologies Inc.
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Carbon or O
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carbon capture
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climate engineering
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Dimensional energy
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ebb carbon
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Fordra
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global thermostat
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Heirloom Carbon Technology
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Yuanwang Laboratory
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Lanze Technology
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Liquid Wind
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lithograph
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activated carbon
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martian material
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Mercury Biorefining
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Zero Task Technology
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Pebble
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prometheus fuel
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repair
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sunfire co., ltd.
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Sustra
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swant
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Travertine Technology
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Victoria
Key topics covered:
1 Research Methods
1.1 Definition of Carbon Capture, Utilization and Storage (CCUS)
2 Executive summary
2.1 Main sources of carbon dioxide emissions
2.2 CO2 as a commodity
2.3 Achieving climate goals
2.4 Market Drivers and Trends
2.5 Current Market and Future Outlook
2.6 CCUS Industry Development in 2020-2022
2.7 CCUS investment
2.8 Government CCUS initiatives
2.9 Commercial CCUS Facilities and Programs
2.9.1 Facilities
2.9.2 Items
2.9.3 Network
2.10 CCUS Value Chain
2.11 Major Market Barriers of CCUS
3 Introduction
3.1 What is CCUS?
3.1.1 Carbon capture
3.1.1.1 CO2 capture technology
3.1.2 Carbon Utilization
3.1.2.1 CO2 Utilization Approaches
3.1.3 Carbon storage
3.2 Transporting CO2
3.2.1 CO2 transport methods
3.2.2 Security
3.2.3 CO2 capture costs in key sectors
3.2.4 CO2 Transportation Costs
3.3 Application
3.3.1 Oil and gas
3.3.1.1 Key technologies of CCUS
3.3.2 Power generation
3.3.2.1 Key technologies of CCUS
3.3.2.2 Carbonate fuel cell capture
3.3.2.3 Retrofitting coal and gas-fired power plants
3.3.3 Steel production
3.3.3.1 Key technologies of CCUS
3.3.4 Blue Hydrogen Production
3.3.4.1 Key technologies of CCUS
3.3.5 Cement and concrete
3.3.5.1 Key technologies of CCUS
3.3.6 Chemical production
3.3.6.1 Key technologies of CCUS
3.3.7 Marine ships
3.3.7.1 Capturing CO2 emissions from ships
3.4 Fees
3.5 Carbon pricing
4 Carbon capture
4.1 CO2 capture from point sources
4.1.1 Cost
4.1.2 Transportation
4.1.3 Global point source CO2 capture capacity
4.2 Main carbon capture processes
4.2.1 Secondary combustion
4.2.2 Oxygen-enriched combustion
4.2.3 Liquid or supercritical CO2: Allam-Fetvedt cycle
4.2.4 Pre-combustion
4.3 Carbon separation technology
4.3.1 Adsorption and absorption capture
4.3.2 Membrane
4.3.3 Liquid or supercritical CO2 (cryogenic) capture
4.3.4 Other technologies
4.3.5 Comparison of main separation technologies
4.4 CO2 capture costs
4.5 Carbon dioxide capture capacity in 2021
4.6 Carbon capture capacity projections by capture type
4.7 Prediction of carbon capture capacity by end use
4.8 Bioenergy with Carbon Capture and Storage (BECCS)
4.8.1 Technical overview
4.8.2 Advantages and disadvantages of BECCS
4.8.3 BECCS facilities
4.8.4 Challenges
4.9 Direct Air Capture (DAC)
4.9.1 Description
4.9.2 Deployment
4.9.3 Point source carbon capture vs. direct air capture
4.9.4 Technology
4.9.4.1 High temperature (HT) aqueous solution
4.9.4.2 Low temperature solid adsorbent DAC
4.9.4.3 High and low temperature comparison Low temperature DAC
4.9.5 Commercialization
4.9.6 Solid adsorbents
4.9.7 Liquid solvents
4.9.8 Metal Organic Frameworks (MOFs) in DACs
4.9.9 DAC plants and projects – current and planned
4.9.10 CO2 storage capacity to 2050
4.9.11 CO2 capture projections for 2030, 2050 and 2070
4.9.12 DAC Market
4.9.13 Fees
4.9.14 Challenges
4.9.15 Players and Productions
4.10 Other “Negative Emissions” Technologies (NETs)
4.10.1 Enhanced weathering and ocean alkalinization
4.10.2 Biochar
4.10.3 Afforestation and reforestation
4.10.4 Soil carbon sequestration
4.10.5 Ocean fertilization
4.10.6 Ocean alkalization
5 Carbon Utilization
5.1 Overview
5.1.1 Market Status
5.1.1.1 Scalability
5.1.1.2 Competition
5.1.1.3 CO2 Utilization Market Forecast
5.1.2 Carbon utilization benefits
5.1.3 Challenges
5.2 Co2 Utilization Approach
5.3 Conversion process
5.3.1 Electrochemical conversion of CO2
5.3.2 Photocatalytic and photothermal catalytic conversion of CO2
5.3.3 Catalytic conversion of CO2
5.3.4 Biotransformation of CO2
5.3.5 Copolymerization of CO2
5.3.6 Carbonation of minerals
5.3.7 Life cycle assessment
5.4 CO2 Derivatives
5.4.1.1 Fuels
5.4.1.2 Chemicals
5.4.1.3 Construction materials
5.4.1.4 Use of CO2 in bioaugmentation
5.5 Utilization of CO2 in EOR
5.5.1 Overview
5.5.1.1 Sources of CO2
5.5.1.2 Principles of enhanced oil recovery (EOR)
5.5.2 CO2-EOR facilities and projects
5.5.3 CO2-EOR Market Analysis and Forecast
5.5.4 Challenges
5.5.5 Major Players
5.6 Carbon mineralization
5.6.1 Advantages
5.6.2 Challenges
5.6.3 In situ mineralization
5.7 Major Players
6 Carbon storage
6.1 Storage Technology and Mechanism
6.1.1 Structure
6.1.2 Residuals
6.1.3 Dissolution
6.1.4 Mineral capture
6.2 CO2 Storage Sites
6.2.1 Storage types of geological storage
6.2.2 Oil and gas fields
6.2.3 Salt formation
6.3 Global CO2 storage potential
6.4 Storage costs
6.5 Fees
6.6 Challenges
7 COMPANY PROFILES (191 company profiles)
8 References
For more information on this report, please visit https://www.researchandmarkets.com/r/eer4zs