2026-2032 年捕碳封存市場（按應用、儲存方法、最終用戶產業和地區分類）

捕碳封存（CCS）市場評估，2026-2032

旨在遏制溫室氣體排放的全球法規日益嚴格，正在推動各行各業採用碳捕獲技術。隨著世界各國根據《巴黎協定》制定雄心勃勃的氣候目標，發電、煉鋼、水泥等產業面臨減少碳排放的壓力。 CCS 提供了一種可行的解決方案，它直接從這些排放源捕獲二氧化碳並防止其進入大氣。此外，研發投入的增加也推動了 CCS 技術的進步，使其更有效率、更具成本效益。捕獲方法、運輸基礎設施和地質儲存解決方案的進步正在幫助擴大CCS市場，預計到2024年銷售額將達到43億美元以上，到2032年將達到54.6億美元。

此外，CCS市場正受到技術創新的驅動。富氧燃燒和直接空氣捕獲等新技術能夠更有效地從工業製程甚至環境空氣中分離二氧化碳。這些技術進步對於提高二氧化碳捕獲系統的效率至關重要。此外，運輸基礎設施的進步，例如更好的二氧化碳油輪設計和改進的管道，使得捕獲的碳能夠有效運輸。最後，地質儲存方案的改進，例如改進的監測方法和場地特性，確保了捕獲的二氧化碳的安全、長期儲存，使 CCS 成為更可靠、更有吸引力的氣候變遷緩解方案。預計未來幾年市場將穩定成長，2026 年至 2032 年的複合年成長率約為 3.33%。

捕碳封存市場定義/概述

在發電廠和工業排放的二氧化碳（CO2）進入環境之前將其捕獲的技術是捕碳封存（CCS）領域的核心。然後，這些二氧化碳可以被捕獲並轉移到地質結構中，例如鹽水層或枯竭的石油和天然氣蘊藏量，在那裡可以無限期地儲存。作為減少溫室氣體排放的一種手段，CCS是應對氣候變遷的重要武器。 CCS應用範圍廣泛，重點是二氧化碳排放高​​的地區。 CCS 可以使天然氣和燃煤發電廠大幅減少排放。同樣，水泥廠、鋼鐵廠和煉油廠等工業設施可以封存其運作過程中排放的二氧化碳。 CCS市場前景光明。由於嚴格的環境法和投資者對永續解決方案的興趣日益濃厚，市場正在不斷擴大。由於捕獲技術、運輸基礎設施和儲存技術的改進，CCS 變得更加高效和經濟。在世界努力實現淨零排放的背景下，捕碳封存（CCS）有望成為多個產業脫碳和減輕氣候變遷影響的關鍵因素。

日益嚴格的環境法規是否會推動捕碳封存市場的成長？

各國政府正向排放大量溫室氣體（尤其是二氧化碳）的產業施壓，要求遵守日益嚴格的法規。可能的例子有水泥廠、鋼鐵廠、煉油廠和發電廠。 CCS技術將使這些產業能夠繼續運轉，並大幅減少碳排放。透過將排放氣體儲存在地下，在它們被釋放到環境之前將其捕獲，公司可以遵守法規並避免問題。

許多司法管轄區正在考慮和實施碳定價策略，包括總量管制與交易和碳排放稅。這些計劃對碳排放徵收價格，增加了企業的污染成本。在這種情況下，CCS 開始具有經濟意義。透過捕獲和儲存排放，企業可以減少其整體碳排放影響並避免繳納高額的碳排放稅。希望這樣的經濟獎勵能夠鼓勵對 CCS 技術的投資。

捕獲設備的高成本是否會阻礙碳捕獲和儲存市場的成長？

捕碳封存（CCS）市場的主要障礙之一是CCS捕獲設備成本高。對於已經面臨競爭的公司來說，與堅持當前做法相比，在 CCS 設備上進行大量的前期投資似乎存在財務風險。這種猶豫阻礙了企業進行 CCS 投資，從而限制了流入市場的資本數量。儘管 CCS 具有潛在的環境效益，但資金的缺乏阻礙了該技術的大規模研究和實施，減緩了市場擴張。

即使公司有能力為 CCS 設備的初始投資提供資金，捕碳封存(CCS) 市場的成長也可能因持續的營運成本而受到嚴重阻礙。捕獲碳的過程需要消耗更多的能源，從而增加成本。收集設備的維修和保養成本也很高。這些因素限制了公司的利潤率，並使他們不願採用 CCS，特別是如果減少排放所節省的成本不能立即顯現出來。這阻礙了 CCS 的廣泛採用並減緩了 CCS 市場的整體擴張。當環境效益不能立即轉化為現金回報時尤其如此。

CCS 捕獲設備的高成本及其採用的有限性限制了捕碳封存(CCS) 領域的擴張。 CCS 可能只對少數擁有雄厚財力的大型工業排放具有實用性。儘管該技術是整體排放的主要原因，但對於中小型企業來說，其成本卻過高。結果是，市場出現分化，大公司可以使用 CCS 作為解決方案，而中小型公司卻沒有切實可行的方法來減少碳排放。這種有限的範圍大大降低了 CCS 作為更廣泛的排放策略的整體有效性。 CCS 只有讓更多的人而不是少數人能夠使用，才能充分發揮其潛力。

地質儲存的使用增加是否會推動捕碳封存市場的成長？

捕獲的二氧化碳（CO2）地質儲存的使用日益增多，對推動捕碳封存（CCS）市場具有巨大的潛力。鹽水含水層和枯竭的石油和天然氣蘊藏量是可以為捕獲的二氧化碳提供安全、長期儲存的深層地質構造的例子。二氧化碳一旦進入，就會儲存在這些地質構造中，數千年內都無法再釋放。這可以理解為防止溫室氣體排放到大氣中、減緩氣候變遷的長期策略。安全儲存要素增強了 CCS 的環境合理性，使其成為應對氣候變遷及其帶來的環境挑戰的更強力的武器。

支持 CCS 長期可行性和擴充性的關鍵要素是地質儲存。與其他有限的封存技術相比，地質構造提供了巨大的二氧化碳容量。這些地質構造，如海水含水層和枯竭的石油和天然氣蘊藏量，可以儲存大量捕獲的二氧化碳。這種巨大的儲存容量意味著，隨著 CCS 得到更廣泛的應用，它可以幫助管理各行各業排放的大量二氧化碳。為了使 CCS 充分發揮其潛力，擴充性至關重要。 CCS 在應對氣候變遷中發揮關鍵作用，因為它可以安全、永久地將越來越多的二氧化碳封存在地下。

透過成本最佳化，地質儲存為 CCS 業務的成長提供了兩大優勢：首先，與其他更受限制的儲存選項相比，地質構造的巨大容量使其能夠進行有效儲存，從而有可能降低每單位二氧化碳的儲存成本。其次，可以利用石油和天然氣產業現有的基礎設施進行二氧化碳的注入和運輸。枯竭的油氣儲存可用作儲存設施，天然氣管道可改造用於運輸二氧化碳。透過利用現有的基礎設施，可以顯著降低建設新倉儲設施的初始成本。這些成本最佳化使 CCS 成為更廣泛行業中具有經濟吸引力的提案，特別是那些先前由於高昂的儲存成本而無法進入的行業。透過降低進入的經濟門檻，地質儲存可以在擴大 CCS 市場和使該技術成為應對氣候變遷的更易於使用的工具方面發揮關鍵作用。

競爭格局

捕碳封存（CCS）市場是一個新興市場，老牌能源公司和創新新興企業之間的競爭非常激烈。石油和天然氣行業的現有企業將帶來其在大型計劃上的工作經驗，而新參與企業將提供新的技術解決方案。這種動態正在引發捕獲方法（燃燒前、燃燒後、富氧燃料）、運輸選擇（管道、船舶）和儲存解決方案（地質構造）方面的競爭。未來幾年，隨著市場逐漸成熟，我們預計會看到更多的整合和策略聯盟。

2024年5月，國際能源總署（IEA）發布了碳捕獲、利用和儲存（CCUS）部署的最新進展。報告強調了顯著的成長，宣布的2030年捕獲能力將與前一年同期比較增35%，到2023年儲存能力將成長70%。這標誌著全球CCS計劃的加速發展。

印度海峽研究公司 2024 年 4 月發布的一份報告預測，到 2032 年，全球捕碳封存(CCS) 市場規模將達到 52.6 億美元，複合年成長率為 6.5%，表明 CCS 技術市場正在擴大。

目錄

第1章 引言

• 市場定義
• 市場區隔
• 調查方法

第2章執行摘要

• 主要發現
• 市場概覽
• 市場亮點

第3章市場概述

• 市場規模和成長潛力
• 市場趨勢
• 市場促進因素
• 市場限制
• 市場機會
• 波特五力分析

第4章捕碳封存市場（依應用）

• 發電
• 石油和天然氣加工
• 工業生產
• 直接空氣捕獲

第5章捕碳封存市場（以儲存方式）

• 地質儲存
• 海洋儲存
• 礦業

第6章捕碳封存市場（依最終用戶產業）

• 能源領域
• 石油和天然氣
• 工業部門
• 其他最終用戶

第7章區域分析

• 北美洲
• 美國
• 加拿大
• 墨西哥
• 歐洲
• 英國
• 德國
• 法國
• 義大利
• 亞太地區
• 中國
• 日本
• 印度
• 澳洲
• 拉丁美洲
• 巴西
• 阿根廷
• 智利
• 中東和非洲
• 南非
• 沙烏地阿拉伯
• 阿拉伯聯合大公國

第8章市場動態

• 市場促進因素
• 市場限制
• 市場機會
• COVID-19 市場影響

第9章 競爭態勢

• 主要企業
• 市場佔有率分析

第10章 公司簡介

• ExxonMobil Corporation（USA）
• Schlumberger Limited（USA）
• Chevron Corporation（USA）
• Shell plc（UK/Netherlands）
• National Oil Corporation（UAE）
• Baker Hughes Company（USA）
• Mitsubishi Heavy Industries, Ltd.（Japan）
• Fluor Corporation（USA）
• SaskPower（Canada）
• China National Petroleum Corporation（China）

第11章 市場展望與機會

• 新興技術
• 未來市場趨勢
• 投資機會

第12章 附錄

• 簡稱列表
• 來源和參考文獻

Carbon Capture and Storage Market Valuation - 2026-2032

The increasing stringent global regulations aimed at curbing greenhouse gas emissions are pushing industries towards adopting carbon capture technologies. As countries worldwide set ambitious climate goals aligned with the Paris Agreement, industries like power generation, steel manufacturing, and cement production are facing mounting pressure to reduce their carbon footprint. CCS offers a viable solution by capturing CO2 emissions directly from these sources, preventing them from entering the atmosphere. Furthermore, growing investments in research and development are leading to advancements in CCS technology, making it more efficient and cost-effective. Advancements in capture methods, transportation infrastructure, and geological storage solutions are contributing to a more robust CCS market expansion is predicted to push market sales above USD 4.3 Billion in 2024 and reach USD 5.46 Billion by 2032.

Furthermore, the market for CCS is driven by innovation. New technologies like oxy-fuel combustion and direct air capture allow more effective CO2 separation from industrial processes and even the ambient air. These technological advancements are crucial for improving the efficiency of CO2 capture systems. Furthermore, the effective delivery of captured carbon is being made possible by advancements in transportation infrastructure, such as better CO2 tanker designs and upgraded pipelines. Last but not least, improvements in geological storage options, such as improved monitoring methods and site characterization, are guaranteeing the safe and long-term sequestration of CO2 captured, making CCS a more dependable and alluring climate change mitigation option. The market is expected to rise steadily in the coming years to grow at a CAGR of about 3.33% from 2026 to 2032.

Carbon Capture and Storage Market: Definition/ Overview

The technologies that capture carbon dioxide (CO2) emissions from power plants and industrial operations before they enter the environment are at the center of the Carbon Capture and Storage (CCS) sector. After being captured, this CO2 is moved and kept indefinitely in geological formations such as saline aquifers or exhausted oil and gas reserves. As a means of reducing greenhouse gas emissions, CCS is an essential weapon in the battle against climate change. CCS has a wide range of applications, with an emphasis on sectors with large CO2 footprints. With CCS, power plants that run on natural gas or coal can cut their emissions considerably. Likewise, industrial establishments such as cement plants, steel mills, and refineries have the ability to sequester carbon dioxide emissions that arise from their operations. The market for CCS seems to have a bright future. The market is expanding as a result of strict environmental laws and rising investor interest in sustainable solutions. CCS is becoming more efficient and economical with improvements in capture technologies, transportation infrastructure, and storage techniques. Carbon capture and storage (CCS) is expected to be a key component in decarbonizing multiple industries and reducing the effects of climate change as the world works toward net-zero emissions.

Will Increasing Stricter Environmental Regulations Fuel the Growth of the Carbon Capture And Storage Market?

The growing stricter environmental regulations are expected to be a major driver for the growth of the carbon capture and storage (CCS) market, Governments everywhere are putting more pressure on sectors that produce considerable amounts of greenhouse gas emissions, especially carbon dioxide (CO2), to comply with their increasingly stringent regulations. Cement factories, steel mills, refineries, and power plants may be examples of this. These sectors can continue to function while drastically lowering their carbon footprint thanks to CCS technology. Companies can comply with regulations and stay out of trouble by storing emissions underground and catching them before they hit the environment.

Numerous areas are investigating or putting into practice carbon pricing strategies including cap-and-trade or carbon taxes. These systems impose a price on carbon emissions, increasing the cost of pollution for businesses. In this case, CCS starts to make economical sense. Businesses can lessen their overall carbon impact and possibly avoid paying hefty carbon taxes by capturing and storing their emissions. It is anticipated that this financial incentive will stimulate investment in CCS technologies.

Will the High Cost of Capture Equipment Hinder the Growth of the Carbon Capture And Storage Market?

The high cost of capture equipment is undeniably a significant roadblock for the growth of the carbon capture and storage (CCS) market, One of the main obstacles to the market for carbon capture and storage (CCS) is the high cost of CCS capture units. Compared to sticking with present practices, organizations who are already up against competition may find it financially risky to make the large upfront investment in CCS equipment. This reluctance deters businesses from making CCS investments, which in turn restricts the total amount of money entering the market. Despite the potential environmental benefits of CCS, this shortage of finance slows down the market's expansion by impeding the technology's larger-scale research and implementation.

Carbon Capture and Storage (CCS) market growth may be severely impeded by ongoing operating costs, even in cases where corporations are able to finance the initial investment in CCS equipment. The act of capturing needs more energy, which raises costs. The cost of servicing and maintaining the capture equipment is an additional expense. These elements limit a company's profit margins, which deters them from embracing CCS, particularly if the cost savings from lower emissions aren't immediately evident. This deters broad adoption and impedes the CCS market's overall expansion. Businesses are reluctant to spend money on technologies that could reduce their earnings, particularly if the environmental advantages don't result in quick cash returns.

The limited application caused by the high cost of CCS capture equipment limits the expansion of the carbon capture and storage (CCS) sector. A small number of large-scale industrial emitters with significant financial resources may be the only ones for whom CCS is practical. Despite being major contributors to overall emissions, smaller and medium-sized enterprises can find the technology prohibitively expensive. This results in a market that is divided into two tiers, with larger companies having the capacity to use CCS as a solution and smaller players having no practical way to lower their carbon footprint. This restricted applicability severely reduces CCS's overall efficacy as a strategy for more extensive emissions reduction. Only when the technology is made available to a larger number of businesses rather than just a few will CCS reach its full potential.

Will Increasing Usage of Geological Storage Drive the Growth of the Carbon Capture And Storage Market?

The increasing utilization of geological storage for captured carbon dioxide (CO2) holds immense potential to propel the carbon capture and storage (CCS) market forward, The benefits of CCS for the environment are greatly increased by its secure geological storage component. Saline aquifers and exhausted oil and gas reserves are examples of deep subterranean formations that provide as secure, long-term storage for captured CO2. Once introduced, the CO2 is stored in these geological formations and cannot be released again for thousands of years. This can be understood as a long-term strategy to prevent greenhouse gas emissions from entering the atmosphere and so mitigate climate change. The environmental justification for CCS is strengthened by the secure storage component, which makes it a more potent weapon in the battle against climate change and the environmental problems it causes.

One important element supporting CCS's long-term viability and scalability is geological storage. In contrast to other constrained storage techniques, geological formations provide enormous CO2 capacity. These formations can store enormous amounts of CO2 that have been captured, much like saltwater aquifers and exhausted oil and gas reserves. This enormous storage capacity gives hope that, when CCS is used more extensively, it will be able to manage the rising volumes of CO2 emissions that will be captured from different industries. For CCS to realize its full potential, scalability is essential. CCS is a key participant in the fight against climate change because it can safely and permanently store ever-increasing volumes of CO2 underground, making it a more practical and scalable approach for reaching aggressive emissions reduction targets.

Through cost optimization, geological storage has a twofold advantage for the growth of the CCS business. First off, compared to other, more constrained storage choices, the enormous capacity of these formations enables effective storage, possibly lowering storage costs per unit of CO2. Second, CO2 injection and transportation can be done with already-existing infrastructure from the oil and gas sector. Depleted oil and gas reservoirs can be used as storage facilities, and natural gas pipelines can be modified to carry CO2. The initial expenditures involved in constructing brand-new storage facilities are greatly decreased by utilizing this current infrastructure. This cost optimization makes CCS a more financially attractive proposition for a wider range of industries, particularly those that were previously priced out due to high storage costs. By reducing the financial barrier to entry, geological storage can play a key role in expanding the CCS market and making the technology a more accessible tool for combating climate change.

Competitive Landscape

The Carbon Capture and Storage (CCS) market is a developing field with a mix of established energy companies and innovative startups vying for position. Incumbent firms in the oil and gas sector leverage their experience in handling large-scale projects, while new entrants bring fresh technology solutions. This dynamic creates competition in capture methods (pre-combustion, post-combustion, oxyfuel), transportation options (pipelines, ships), and storage solutions (geological formations). The coming years will likely see consolidation and strategic partnerships as the market matures.

Some of the prominent players operating in the carbon capture and storage market include:

ExxonMobil Corporation

Schlumberger Limited

Chevron Corporation

Shell plc

National Oil Corporation

Baker Hughes Company

Mitsubishi Heavy Industries, Ltd.

Fluor Corporation

SaskPower

China National Petroleum Corporatio

In May 2024, The International Energy Agency (IEA) released an update on Carbon Capture, Utilization and Storage (CCUS) deployment. The report highlights significant growth, with announced capture capacity for 2030 increasing by 35% and storage capacity by 70% in 2023 compared to the previous year. This indicates an acceleration in CCS projects around the world.

In April 2024, A report by India-based Straits Research projects the global carbon capture and storage (CCS) market to reach $5.26 billion by 2032. This reflects a compound annual growth rate (CAGR) of 6.5%, indicating a growing market for CCS technologies.

TABLE OF CONTENTS

1. Introduction

• Market Definition
• Market Segmentation
• Research Methodology

2. Executive Summary

• Key Findings
• Market Overview
• Market Highlights

3. Market Overview

• Market Size and Growth Potential
• Market Trends
• Market Drivers
• Market Restraints
• Market Opportunities
• Porter's Five Forces Analysis

4. Carbon Capture and Storage Market, By Application

• Power Generation
• Oil and Gas Processing
• Industrial Manufacturing
• Direct Air Capture

5. Carbon Capture and Storage Market, By Storage Method

• Geological Storage
• Ocean Storage
• Mineralization

6. Carbon Capture and Storage Market, By End User Industry

• Energy Sector
• Oil and Gas Industry
• Industrial Sector
• Other Sectors

7. Regional Analysis

• North America
• United States
• Canada
• Mexico
• Europe
• United Kingdom
• Germany
• France
• Italy
• Asia-Pacific
• China
• Japan
• India
• Australia
• Latin America
• Brazil
• Argentina
• Chile
• Middle East and Africa
• South Africa
• Saudi Arabia
• UAE

8. Market Dynamics

• Market Drivers
• Market Restraints
• Market Opportunities
• Impact of COVID-19 on the Market

9. Competitive Landscape

• Key Players
• Market Share Analysis

10. Company Profiles

• ExxonMobil Corporation (USA)
• Schlumberger Limited (USA)
• Chevron Corporation (USA)
• Shell plc (UK/Netherlands)
• National Oil Corporation (UAE)
• Baker Hughes Company (USA)
• Mitsubishi Heavy Industries, Ltd. (Japan)
• Fluor Corporation (USA)
• SaskPower (Canada)
• China National Petroleum Corporation (China)

11. Market Outlook and Opportunities

• Emerging Technologies
• Future Market Trends
• Investment Opportunities

12. Appendix

• List of Abbreviations
• Sources and References