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EN21128524 |
Pages: 241 |
Dec 2021 |
The global carbon capture, utilization, and storage market accounted for $1,912.9 million in 2020 and is predicted to grow with a CAGR of 13.7%, by generating a revenue of $5,306.7 million by 2028.
Carbon capture, utilization, and storage market is gaining huge popularity owing to its role in reducing the emission of harmful greenhouse gases. For instance, carbon capture, utilization, and storage (CCUS) technology captures the carbon dioxide emissions from coal-fired power plants which is then utilized or reused and stored to prevent its emission into the atmosphere. Tackling the emissions from existing industrial and power plants can reduce 600 billion tons of carbon dioxide emissions in next five years.
However, technology is expensive as more energy is needed to concentrate CO2 molecules that can be captured and utilized further. In addition, the cost of purchasing the equipment for capturing CO2 and its compression is high. These factors are anticipated to restrain the carbon capture, utilization, and storage market size during the analysis timeframe.
The role of CCUS in sustainable development and in transition to net-zero emission is estimated to attract excellent growth opportunities. This is majorly owing to the role of CCUS in reducing the carbon emissions across the energy systems which is technically expensive. In addition, carbon capture, utilization, and storage can offset the carbon emission from outside the energy sector. Also, CCUS accounts for 15% of cumulative CO2 reduction worldwide.
According to regional analysis, the North America carbon capture, utilization, and storage market accounted for $807.1 million in 2020 and is predicted to grow with a CAGR of 13.9% in the projected timeframe.
Carbon capture, utilization, and storage is an important technology that plays a major role in reducing the carbon dioxide emissions from fossil-fuel powered power plants as well as from various industrial activities. CCUS technology is vital in offering dispatchable and low-carbon electricity. By 2040, CCUS is estimated to generate 5% of the global power. Along with reducing the emissions from fossil fuels such as oil, coal, and natural gas-based power plants, CCUS can also capture the carbon emissions from concrete, cement, or aggregate plants from the construction sector. Hence, the ambitious targets for climate neutrality by preventing CO2 emissions into the atmosphere can be achieved.
The global crisis caused by COVID-19 pandemic has driven the world into deep recession. This has led to slump in economic activities that has negatively affected the carbon capture, utilization, and storage market. This is majorly owing to shift in government focus and investments in the healthcare sector. The global economy is set to shrink along with significant decline in the gross domestic product (GDP) in every country affected by COVID-19 pandemic. The International Energy Agency (IEA), the Paris-based autonomous intergovernmental organization, states that the investments in clean energy technologies including CCUS could plunge by as much as 20%. In addition, delays and cancellation in the new CCUS projects owing to economic downturn as majority of the oil & gas companies involved in CCUS projects have faced significant reductions in the capital spending in 2020.
Various government initiatives and plans to invest massively for economic recovery and to stimulate investments in carbon capture, utilization, and storage market are estimated to generate huge growth opportunities. For instance, significant increase in the number of new funding announcements in CCUS projects across the world is estimated to drive carbon capture, utilization, and storage market growth post-pandemic. For instance, in March 2020, the UK government announced an investment of USD 995 million for the development of CCUS infrastructure. This investment will facilitate the development of CCUS plants in at least two industrial locations along with gas-fired power plants. In addition, in September 2020, the U.S. government announced USD 72 million in CCUS grants which is estimated to boost the carbon capture, utilization, and storage market share post-pandemic.
The power plants fueled by coal and gas dominate the global electricity generation sector. Despite the advent of renewable energy sources for power generation, the power generated from fossil fuel still dominates the energy sector. Coal is the largest source of power generation followed by gas. Hence, power is the largest carbon emitting sector that accounts for more than 40% of carbon emissions. Hence, to lower the emissions from such power plants, the carbon capture, utilization, and storage technology plays a vital role. For instance, retrofitting the power sector with CCUS technologies can help in reducing the carbon emissions from the existing plants. Hence, this technology plays a major role in promoting energy security and meeting net-zero climate objectives and enhancing the portfolio of low-carbon supply sources. IEA estimates that by 2040, CCUS-equipped plants will provide 1900 TWh of global power. These factors are estimated to drive the carbon capture, utilization, and storage market demand during the forecast period.
To know more about global carbon capture, utilization, and storage market drivers, get in touch with our analysts here.
High implementation cost is one of the major barriers for the implementation of CCUS technology across the world. For instance, the cost of carbon capturing, and its compression is high as it decreases the efficiency of power plants and increases the water requirement. This creates a major issue for the power plants that are already facing scarcity of water. In addition, research & development cost associated with the full-scale deployment of carbon capture, utilization, and storage is estimated to restrain the market growth during the forecast period.
The carbon capture, utilization, and storage technologies are set to play a major role towards clean energy transitions in Asia-Pacific region. This is majorly owing to the role of CCUS technology in addressing the carbon emissions from existing power plants & industrial assets. This will also promote the development of new economic opportunities for producing low carbon hydrogen and ammonia. For instance, as stated on June 22, 2021, in the Argus Media, the independent media organization, Japan drives the carbon capture, utilization, and storage projects in the Asia-Pacific region. This is majorly owing to growing investments and funding for these projects to achieve carbon neutrality by 2050. For instance, in June 2021, the Japanese government proposed $10 billion funding to support renewable and low-cost projects under the Asia Energy Transition Initiative.
To know more about global carbon capture, utilization, and storage market opportunities, get in touch with our analysts here.
[SERVICEGRAPH]
Source: Research Dive Analysis
The capture sub-segment is anticipated to have a dominant market share and generate a revenue of $3,753.2 million by 2028, growing from $1,318.3 million in 2020. Carbon capture is the first step in the CCUS technology which is an integral process to reduce the emission of carbon dioxide from various industrial processes. Some of the widely adopted carbon capture technologies are chemical absorption, physical separation, chemical looping, calcium looping, and others. Carbon capture process can be applied to any large-scale emission process such as coal-fired power plants, oil & gas plants, cement industry, and iron & steel industry for capturing CO2 from the source and preventing its release into the atmosphere. These factors are estimated to drive the growth of capture sub-segment during the analysis timeframe.
The utilization sub-segment is anticipated to show the fastest growth and shall generate a revenue of $564.6 million by 2028, growing from $195.9 million in 2020. The captured CO2 finds variety of applications which include direct used of CO2 which is not chemically altered for various chemical and biological processes. Some of the potential applications include the use of CO2 for yield boosting, heat transfer fluids, and in solvents. For instance, the International Energy Agency, the Paris-based Organization for Economic Co-operation and Development, at present 230 Mt of CO2 is utilized for producing fertilizers and for enhanced oil recovery process.
[TECHNOLOGYGRAPH]
Source: Research Dive Analysis
The post-combustion capture sub-segment is anticipated to have a dominant market share and generate a revenue of $2,450.4 million by 2028, growing from $873.5 million in 2020. The post-combustion process involves capturing CO2 from flue gas which is generated via combustion of fuels such as coal or natural gas. As stated in National Energy Technology Laboratory, which delivers integrated solutions to enable transformation to a sustainable energy future, out of 4 trillion kilowatt hours of electricity generated in 2019 in the U.S., 38% of it was generated from natural gas and 23% was generated from coal. As more than 60% of electricity is generated from fossil fuel power plants, deployment of post-combustion capture technologies is vital to minimize the CO2 emissions.
The oxy-fuel combustion capture sub-segment is anticipated to show the fastest growth and shall generate a revenue of $1,920.2 million by 2028, growing from $663.2 million in 2020. The oxy-fuel combustion capture involves the process of burning the fuel with nearly pure oxygen instead of air. This method is gaining popularity as it produces exhaust gas which is mainly water vapor and CO2 which can be easily separated for the production of high purity CO2 stream. This process successfully removes all the nitrogen from the air yielding approximately 95% oxygen.
[ENDUSEGRAPH]
Source: Research Dive Analysis
The oil & gas sub-segment is anticipated to have a dominant market share and generate a revenue of $2,917.6 million by 2028, growing from $1,075.8 million in 2020. In oil & gas industry, the carbon capture, utilization, and storage technology is widely used to prevent the release of greenhouse gases into the atmosphere. The oil & gas industry stores the carbon dioxide for the deep, offshore, or onshore geological formations, where it is used for enhanced oil recovery. For instance, in 2019, around 24 million tons of CO2 was captured, stored, and utilized by the oil & gas sector which was majorly extracted from natural gas processing plants. As per the Energy Information Administration (EIA), which offers official energy statistics from the U.S., natural gas generation is estimated to show a growth rate of approximately 2.7% every year between 2012 and 2040. This is estimated to account for 30% of global energy generation by 2040. Hence, the utilization of captured CO2 in oil & gas sector is estimated to boost the demand for carbon capture, utilization, and storage market in the upcoming years.
The iron & steel sub-segment is anticipated to show the fastest growth and shall generate a revenue of $721.4 million by 2028, growing from $232.2 million in 2020. Iron & steel production process is one of the leading carbon emission sources. For instance, steel mills comprise of number of furnaces and subunits that are involved in the emission of carbon dioxide. Among these, blast furnaces and on-site power plants emit more CO2. Hence, to reduce the carbon footprint and to promote sustainable development in iron & steel sector, adoption of CCUS technologies is gaining huge popularity.
[REGIONGRAPH]
Source: Research Dive Analysis
The North America carbon capture, utilization, and storage market accounted $807.1 million in 2020 and is projected to grow with a CAGR of 13.9%. North America region leads the world in carbon capture, utilization, and storage with enhanced oil recovery (EOR) contributing to the significant growth. This is majorly owing to legal and regulatory landscape that focuses on incorporating CCUS in oil & gas sector across federal, state, and provincial levels. In addition, the Biden-Harris Administration’s goal of net zero emissions by 2050, is anticipated to drive the CCUS demand in this region. For instance, as stated on October 18, 2021, in the Gas World, the leading news portal for global industrial gas sector, the US Department of Energy (DOE) announced a funding of $20 million in October 2021, for four CCUS projects in the U.S. In addition, the emission reduction policy introduced by the Canadian government in July 2015, that places limit on CO2 emissions from coal power plants is estimated to boost the CCUS market demand.
The Europe carbon capture, utilization, and storage market accounted $522.6 million in 2020 and is projected to grow with a CAGR of 14.3%. The ambitious target set by European Union that focuses on at least 40% reduction of greenhouse gases by 2030 is estimated to drive the carbon capture, utilization, and storage market size in the Europe region. Decarbonizing the electricity supply, industrial process such as oil & gas sector and others is a major growth driving factor. At present there are two large scale CCUS projects operational in Norway that captures CO2 emissions from natural gas processing sector. The combined CO2 capturing capacity of these two plants is 1.7 Mt/year. The International Energy Agency (IEA), the Paris-based autonomous intergovernmental organization established in 1974, states that CO2 capture is estimated to rise to 35 Mt in 2030, 350 Mt in 2050, and to more than 700 Mt in 2070 in Europe to boost sustainable development.
Source: Research Dive Analysis
Some of the leading carbon capture, utilization, and storage market players are Royal Dutch Shell plc, Fluor Corporation, Mitsubishi Heavy Industries, Ltd., Linde plc, Exxon Mobil Corporation, JGC Holdings Corporation, Schlumberger Limited, Aker Solutions, Honeywell International Inc., and Halliburton.
Porter’s Five Forces Analysis for the Global Carbon Capture, Utilization, and Storage Market:
Aspect | Particulars |
Historical Market Estimations | 2019-2020 |
Base Year for Market Estimation | 2020 |
Forecast Timeline for Market Projection | 2021-2028 |
Geographical Scope | North America, Europe, Asia-Pacific, LAMEA |
Segmentation by Service |
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Segmentation by Technology |
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Segmentation by End-use |
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Key Companies Profiled |
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1.Research Methodology
1.1.Desk Research
1.2.Real time insights and validation
1.3.Forecast model
1.4.Assumptions and forecast parameters
1.4.1.Assumptions
1.4.2.Forecast parameters
1.5.Data sources
1.5.1.Primary
1.5.2.Secondary
2.Executive Summary
2.1.360° summary
2.2.Service trends
2.3.Technology trends
2.4.End-use trends
3.Market overview
3.1.Market segmentation & definitions
3.2.Key takeaways
3.2.1.Top investment pockets
3.2.2.Top winning strategies
3.3.Porter’s five forces analysis
3.3.1.Bargaining power of consumers
3.3.2.Bargaining power of suppliers
3.3.3.Threat of new entrants
3.3.4.Threat of substitutes
3.3.5.Competitive rivalry in the market
3.4.Market dynamics
3.4.1.Drivers
3.4.2.Restraints
3.4.3.Opportunities
3.5.Technology landscape
3.6.Regulatory landscape
3.7.Patent landscape
3.8.Market value chain analysis
3.9.Strategic overview
4.Carbon Capture, Utilization, and Storage Market, by Service
4.1.Capture
4.1.1.Market size and forecast, by region, 2020-2028
4.1.2.Comparative market share analysis, 2020 & 2028
4.2.Transportation
4.2.1.Market size and forecast, by region, 2020-2028
4.2.2.Comparative market share analysis, 2020 & 2028
4.3.Utilization
4.3.1.Market size and forecast, by region, 2020-2028
4.3.2.Comparative market share analysis, 2020 & 2028
4.4.Storage
4.4.1.Market size and forecast, by region, 2020-2028
4.4.2.Comparative market share analysis, 2020 & 2028
5.Carbon Capture, Utilization, and Storage Market, by Technology
5.1.Pre-Combustion Capture
5.1.1.Market size and forecast, by region, 2020-2028
5.1.2.Comparative market share analysis, 2020 & 2028
5.2.Oxy-Fuel Combustion Capture
5.2.1.Market size and forecast, by region, 2020-2028
5.2.2.Comparative market share analysis, 2020 & 2028
5.3.Post-Combustion Capture
5.3.1.Market size and forecast, by region, 2020-2028
5.3.2.Comparative market share analysis, 2020 & 2028
6.Carbon Capture, Utilization, and Storage Market, by Technology
6.1.Oil and Gas
6.1.1.Market size and forecast, by region, 2020-2028
6.1.2.Comparative market share analysis, 2020 & 2028
6.2.Power Generation
6.2.1.Market size and forecast, by region, 2020-2028
6.2.2.Comparative market share analysis, 2020 & 2028
6.3.Iron and Steel
6.3.1.Market size and forecast, by region, 2020-2028
6.3.2.Comparative market share analysis, 2020 & 2028
6.4.Chemical and Petrochemical
6.4.1.Market size and forecast, by region, 2020-2028
6.4.2.Comparative market share analysis, 2020 & 2028
6.5.Cement
6.5.1.Market size and forecast, by region, 2020-2028
6.5.2.Comparative market share analysis, 2020 & 2028
6.6.Others
6.6.1.Market size and forecast, by region, 2020-2028
6.6.2.Comparative market share analysis, 2020 & 2028
7.Carbon Capture, Utilization, and Storage Market, by Region
7.1.North America
7.1.1.Market size and forecast, by Service, 2020-2028
7.1.2.Market size and forecast, by Technology, 2020-2028
7.1.3.Market size and forecast, by End-use, 2020-2028
7.1.4.Market size and forecast, by country, 2020-2028
7.1.5.Comparative market share analysis, 2020 & 2028
7.1.6.U.S.
7.1.6.1.Market size and forecast, by Service, 2020-2028
7.1.6.2.Market size and forecast, by Technology, 2020-2028
7.1.6.3.Market size and forecast, by End-use, 2020-2028
7.1.6.4.Comparative market share analysis, 2020 & 2028
7.1.7.Canada
7.1.7.1.Market size and forecast, by Service, 2020-2028
7.1.7.2.Market size and forecast, by Technology, 2020-2028
7.1.7.3.Market size and forecast, by End-use, 2020-2028
7.1.7.4.Comparative market share analysis, 2020 & 2028
7.1.8.Mexico
7.1.8.1.Market size and forecast, by Service, 2020-2028
7.1.8.2.Market size and forecast, by Technology, 2020-2028
7.1.8.3.Market size and forecast, by End-use, 2020-2028
7.1.8.4.Comparative market share analysis, 2020 & 2028
7.2.Europe
7.2.1.Market size and forecast, by Service, 2020-2028
7.2.2.Market size and forecast, by Technology, 2020-2028
7.2.3.Market size and forecast, by End-use, 2020-2028
7.2.4.Market size and forecast, by country, 2020-2028
7.2.5.Comparative market share analysis, 2020 & 2028
7.2.6.UK
7.2.6.1.Market size and forecast, by Service, 2020-2028
7.2.6.2.Market size and forecast, by Technology, 2020-2028
7.2.6.3.Market size and forecast, by End-use, 2020-2028
7.2.6.4.Comparative market share analysis, 2020 & 2028
7.2.7.Germany
7.2.7.1.Market size and forecast, by Service, 2020-2028
7.2.7.2.Market size and forecast, by Technology, 2020-2028
7.2.7.3.Market size and forecast, by End-use, 2020-2028
7.2.7.4.Comparative market share analysis, 2020 & 2028
7.2.8.Norway
7.2.8.1.Market size and forecast, by Service, 2020-2028
7.2.8.2.Market size and forecast, by Technology, 2020-2028
7.2.8.3.Market size and forecast, by End-use, 2020-2028
7.2.8.4.Comparative market share analysis, 2020 & 2028
7.2.9.Italy
7.2.9.1.Market size and forecast, by Service, 2020-2028
7.2.9.2.Market size and forecast, by Technology, 2020-2028
7.2.9.3.Market size and forecast, by End-use, 2020-2028
7.2.9.4.Comparative market share analysis, 2020 & 2028
7.2.10.Netherlands
7.2.10.1.Market size and forecast, by Service, 2020-2028
7.2.10.2.Market size and forecast, by Technology, 2020-2028
7.2.10.3.Market size and forecast, by End-use, 2020-2028
7.2.10.4.Comparative market share analysis, 2020 & 2028
7.2.11.Rest of Europe
7.2.11.1.Market size and forecast, by Service, 2020-2028
7.2.11.2.Market size and forecast, by Technology, 2020-2028
7.2.11.3.Market size and forecast, by End-use, 2020-2028
7.2.11.4.Comparative market share analysis, 2020 & 2028
7.3.Asia Pacific
7.3.1.Market size and forecast, by Service, 2020-2028
7.3.2.Market size and forecast, by Technology, 2020-2028
7.3.3.Market size and forecast, by End-use, 2020-2028
7.3.4.Market size and forecast, by country, 2020-2028
7.3.5.Comparative market share analysis, 2020 & 2028
7.3.6.China
7.3.6.1.Market size and forecast, by Service, 2020-2028
7.3.6.2.Market size and forecast, by Technology, 2020-2028
7.3.6.3.Market size and forecast, by End-use, 2020-2028
7.3.6.4.Comparative market share analysis, 2020 & 2028
7.3.7.Japan
7.3.7.1.Market size and forecast, by Service, 2020-2028
7.3.7.2.Market size and forecast, by Technology, 2020-2028
7.3.7.3.Market size and forecast, by End-use, 2020-2028
7.3.7.4.Comparative market share analysis, 2020 & 2028
7.3.8.India
7.3.8.1.Market size and forecast, by Service, 2020-2028
7.3.8.2.Market size and forecast, by Technology, 2020-2028
7.3.8.3.Market size and forecast, by End-use, 2020-2028
7.3.8.4.Comparative market share analysis, 2020 & 2028
7.3.9.South Korea
7.3.9.1.Market size and forecast, by Service, 2020-2028
7.3.9.2.Market size and forecast, by Technology, 2020-2028
7.3.9.3.Market size and forecast, by End-use, 2020-2028
7.3.9.4.Comparative market share analysis, 2020 & 2028
7.3.10.Australia
7.3.10.1.Market size and forecast, by Service, 2020-2028
7.3.10.2.Market size and forecast, by Technology, 2020-2028
7.3.10.3.Market size and forecast, by End-use, 2020-2028
7.3.10.4.Comparative market share analysis, 2020 & 2028
7.3.11.Rest of Asia Pacific
7.3.11.1.Market size and forecast, by Service, 2020-2028
7.3.11.2.Market size and forecast, by Technology, 2020-2028
7.3.11.3.Market size and forecast, by End-use, 2020-2028
7.3.11.4.Comparative market share analysis, 2020 & 2028
7.4.LAMEA
7.4.1.Market size and forecast, by Service, 2020-2028
7.4.2.Market size and forecast, by Technology, 2020-2028
7.4.3.Market size and forecast, by End-use, 2020-2028
7.4.4.Market size and forecast, by country, 2020-2028
7.4.5.Comparative market share analysis, 2020 & 2028
7.4.6.Latin America
7.4.6.1.Market size and forecast, by Service, 2020-2028
7.4.6.2.Market size and forecast, by Technology, 2020-2028
7.4.6.3.Market size and forecast, by End-use, 2020-2028
7.4.6.4.Comparative market share analysis, 2020 & 2028
7.4.7.Middle East
7.4.7.1.Market size and forecast, by Service, 2020-2028
7.4.7.2.Market size and forecast, by Technology, 2020-2028
7.4.7.3.Market size and forecast, by End-use, 2020-2028
7.4.7.4.Comparative market share analysis, 2020 & 2028
7.4.8.Africa
7.4.8.1.Market size and forecast, by Service, 2020-2028
7.4.8.2.Market size and forecast, by Technology, 2020-2028
7.4.8.3.Market size and forecast, by End-use, 2020-2028
7.4.8.4.Comparative market share analysis, 2020 & 2028
8.Company profiles
8.1.Royal Dutch Shell plc
8.1.1.Business overview
8.1.2.Financial performance
8.1.3.Product portfolio
8.1.4.Recent strategic moves & developments
8.1.5.SWOT analysis
8.2.Fluor Corporation
8.2.1.Business overview
8.2.2.Financial performance
8.2.3.Product portfolio
8.2.4.Recent strategic moves & developments
8.2.5.SWOT analysis
8.3.Mitsubishi Heavy Industries, Ltd.
8.3.1.Business overview
8.3.2.Financial performance
8.3.3.Product portfolio
8.3.4.Recent strategic moves & developments
8.3.5.SWOT analysis
8.4.Linde plc
8.4.1.Business overview
8.4.2.Financial performance
8.4.3.Product portfolio
8.4.4.Recent strategic moves & developments
8.4.5.SWOT analysis
8.5.Exxon Mobil Corporation
8.5.1.Business overview
8.5.2.Financial performance
8.5.3.Product portfolio
8.5.4.Recent strategic moves & developments
8.5.5.SWOT analysis
8.6.JGC Holdings Corporation
8.6.1.Business overview
8.6.2.Financial performance
8.6.3.Product portfolio
8.6.4.Recent strategic moves & developments
8.6.5.SWOT analysis
8.7.Schlumberger Limited
8.7.1.Business overview
8.7.2.Financial performance
8.7.3.Product portfolio
8.7.4.Recent strategic moves & developments
8.7.5.SWOT analysis
8.8.Aker Solutions
8.8.1.Business overview
8.8.2.Financial performance
8.8.3.Product portfolio
8.8.4.Recent strategic moves & developments
8.8.5.SWOT analysis
8.9.Honeywell International Inc.
8.9.1.Business overview
8.9.2.Financial performance
8.9.3.Product portfolio
8.9.4.Recent strategic moves & developments
8.9.5.SWOT analysis
8.10.Halliburton
8.10.1.Business overview
8.10.2.Financial performance
8.10.3.Product portfolio
8.10.4.Recent strategic moves & developments
8.10.5.SWOT analysis
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