胺基碳捕获市场机会、成长动力、产业趋势分析及 2025 - 2034 年预测

2024年，全球胺基碳捕集市场规模达6.566亿美元，预计2034年将以6.1%的复合年增长率成长，达到12亿美元。全球正加强应对温室气体排放，尤其是发电厂和重工业排放的二氧化碳。随着各国制定雄心勃勃的碳中和目标，对高效、可扩展且经济高效的碳捕集技术的需求持续成长。胺基碳捕集正成为最可靠的解决方案之一，它提供了一种无需改造现有基础设施即可显着减少排放的实用方法。企业、政府和研究机构正大力投资先进胺溶剂和系统的开发，并认识到其在能源和製造业转型方面的潜力。

推动这一市场发展的不仅是监管压力，还有投资者对永续技术日益增长的兴趣。随着碳定价机制的收紧以及脱碳成为企业策略的核心，企业正在寻求可靠的长期解决方案，以确保合规性并支持永续发展承诺。此外，循环碳经济的日益增长推动了对捕获、回收甚至永久去除二氧化碳的技术的需求。在此背景下，基于胺的碳捕获技术拥有久经考验的性能和灵活性。它目前既可以进行工业规模部署，也可以作为创新平台，包括与碳利用和储存系统的整合。随着材料科学、工艺工程和自动化的进步，预计这一市场将继续快速扩张，为新进业者和老牌企业提供重大机会。

胺基捕集技术以其高效性而闻名，尤其是在燃烧后烟气富含二氧化碳的应用中。此製程依赖胺水溶液以化学方式吸收二氧化碳，然后在再生阶段释放，使溶剂能够连续循环使用。该技术尤其适用于改造现有的燃煤和燃气发电厂以及其他工业设施，无需进行大规模改造。实现气候目标和减少工业碳足迹的紧迫性日益增强，推动该领域的创新，重点是提高溶剂性能、提高二氧化碳负载能力并降低再生所需的能源。

该领域最具前瞻性的发展之一是使用胺类增强固体吸附剂直接捕获空气中的二氧化碳。虽然这项技术比从源头捕获排放物耗能更高，但它有可能透过直接从大气中提取二氧化碳来逆转排放。随着人们的注意力转向净负排放策略，这种方法正受到气候技术投资者和各国政府的青睐。

近期研发工作重点在于提升胺基溶剂的选择性和反应性，旨在降低整体营运成本的同时提高捕集效率。这包括开发具有更高热稳定性和更低降解率的新型溶剂配方。跨部门合作推动创新，化学工程师、环境科学家和清洁能源专家齐心协力，致力于使碳捕集系统更容易大规模部署。这些进步对于水泥、钢铁和炼油等难以减排的产业尤其重要，因为电气化在这些产业中并非可行的脱碳途径。

2024年，单乙醇胺 (MEA) 占据了38.6%的市场份额，占据主导地位。 MEA以其对二氧化碳的强亲和力和形成稳定氨基甲酸酯化合物的能力而闻名，至今仍是化学吸收系统的基石。其可靠性、操作一致性和广泛的可用性使其成为燃烧后碳捕集的首选，尤其是在传统能源基础设施中。

2024年，燃烧后捕集技术以53.1%的市占率领先市场，这主要归功于其与现有系统的无缝整合。各行各业都青睐这种方法，因为它能够在最大程度上减少碳排放，同时最大程度地降低营运中断。经过数十年的试点测试、商业项目和工程改进，燃烧后捕集仍然是最实用、最广泛应用的解决方案。

2024年，美国胺基碳捕集市场规模达1.904亿美元。税收抵免等联邦激励措施，加上灵活的州级法规，使美国成为碳捕集创新领域的领先市场。美国环保署和各州政府部门对六级井的快速审批缩短了专案週期，增强了投资者信心，进一步加速了部署进程。

主要的产业参与者包括东芝能源系统与解决方案公司、林德集团、三菱重工、福陆公司、科赫-格力奇公司、壳牌CANSOLV公司、巴斯夫欧洲公司、滨特尔公司、Carbon Clean公司和基伊埃集团。这些公司致力于提高溶剂再生效率，推出模组化碳捕集装置，并将试点计画扩展到全面的商业营运。他们的努力有助于降低成本，并提高下一代胺系统在广泛工业应用中的可扩展性。

目录

第一章：方法论与范围

第二章：执行摘要

第三章：行业洞察

• 产业生态系统分析
  • 主要製造商
  • 经销商
  • 整个产业的利润率
  • 供应中断
• 川普政府关税
  • 对贸易的影响
    • 贸易量中断
    • 报復措施
  • 对产业的影响
    • 供应方影响（原料）
      • 主要材料价格波动
      • 供应链重组
      • 生产成本影响
    • 需求面影响（售价）
      • 价格传导至终端市场
      • 市占率动态
      • 消费者反应模式
  • 受影响的主要公司
  • 策略产业回应
    • 供应链重构
    • 定价和产品策略
    • 政策参与
  • 展望与未来考虑
• 贸易统计（HS编码）
  • 主要出口国
  • 主要进口国
• 利润率分析
• 重要新闻和倡议
• 监管格局
• 衝击力
  • 成长动力
    • 增加单乙醇胺在燃煤电厂燃烧后二氧化碳捕集中的应用
    • 甲基二乙醇胺混合物用于天然气脱硫的技术改进
    • 使用胺基功能化固体吸附剂的直接空气捕获（DAC）投资不断增加
  • 产业陷阱与挑战
    • 溶剂再生带来的高能量损失和营运成本
    • 某些胺具有腐蚀性，需要昂贵的材料来建造工厂基础设施
• 成长潜力分析
• 波特的分析
• PESTEL分析

第四章：竞争格局

• 介绍
• 公司市占率分析
• 竞争定位矩阵
• 战略展望矩阵

第五章：市场估计与预测：按胺类型，2021-2034 年

• 主要趋势
• 单乙醇胺
• 二乙醇胺
• 甲基二乙醇胺
• 三乙醇胺
• 其他的

第六章：市场估计与预测：按应用，2021 年至 2034 年

• 主要趋势
• 燃烧后捕获
• 燃烧前捕集
• 直接空气捕获
• 其他的

第七章：市场估计与预测：按地区，2021-2034 年

• 主要趋势
• 北美洲
  • 我们
  • 加拿大
• 欧洲
  • 德国
  • 英国
  • 法国
  • 西班牙
  • 义大利
  • 荷兰
• 亚太地区
  • 中国
  • 印度
  • 日本
  • 澳洲
  • 韩国
• 拉丁美洲
  • 巴西
  • 墨西哥
  • 阿根廷
• 中东和非洲
  • 沙乌地阿拉伯
  • 南非
  • 阿联酋

第八章：公司简介

• BASF SE
• Carbon Clean
• Fluor Corporation
• GEA Group
• Koch-Glitsch
• Linde PLC
• Mitsubishi Heavy Industries
• Pentair
• Shell CANSOLV
• Toshiba Energy Systems & Solutions

The Global Amine-Based Carbon Capture Market was valued at USD 656.6 million in 2024 and is estimated to grow at a CAGR of 6.1% to reach USD 1.2 billion by 2034, as global efforts ramp up to combat greenhouse gas emissions, particularly carbon dioxide released from power plants and heavy industries. As countries set ambitious carbon neutrality goals, demand for efficient, scalable, and cost-effective carbon capture technologies continues to rise. Amine-based carbon capture is emerging as one of the most dependable solutions, offering a practical way to significantly reduce emissions without overhauling existing infrastructure. Companies, governments, and research institutions are heavily investing in the development of advanced amine solvents and systems, recognizing their potential to transform the energy and manufacturing sectors.

This market is driven not only by regulatory pressure but also by growing investor interest in sustainable technologies. As carbon pricing mechanisms tighten and decarbonization becomes central to corporate strategies, businesses are seeking reliable, long-term solutions that ensure compliance while supporting sustainability commitments. Moreover, the growing push for circular carbon economies is reinforcing the need for technologies that capture, recycle, and even permanently remove CO2 ,In this context, amine-based carbon capture offers a proven track record of performance and flexibility. It can be deployed at industrial scale today while also serving as a platform for innovation, including integration with carbon utilization and storage systems. With advancements in material science, process engineering, and automation, this market is expected to continue expanding rapidly, offering significant opportunities for new entrants and established players alike.

Amine-based capture technology is known for its high efficiency, particularly in post-combustion applications where flue gases are rich in carbon dioxide. The process relies on aqueous amine solutions to chemically absorb CO2 which is then released during the regeneration phase, allowing the solvent to be reused in continuous cycles. This technology is especially well-suited for retrofitting existing coal and gas-fired power plants, as well as other industrial facilities, without the need for extensive modifications. The increasing urgency to meet climate targets and reduce industrial carbon footprints is pushing innovation in this field, with an emphasis on improving solvent performance, increasing CO2 loading capacity, and reducing the energy required for regeneration.

One of the most forward-looking developments in this space is direct air capture using solid sorbents enhanced with amines. Although more energy-intensive than capturing emissions at the source, this technology holds the potential to reverse emissions by extracting CO2 directly from the atmosphere. As attention shifts toward net-negative emission strategies, this approach is gaining traction among climate tech investors and governments alike.

Recent R&D efforts are focused on improving the selectivity and reactivity of amine-based solvents, aiming to reduce overall operational costs while enhancing capture efficiency. This includes the development of new solvent formulations with higher thermal stability and lower degradation rates. Innovations are being driven by cross-sector collaboration involving chemical engineers, environmental scientists, and clean energy specialists, all working toward making carbon capture systems more viable for large-scale deployment. These advancements are particularly important in hard-to-abate sectors like cement, steel, and refining, where electrification is not a feasible path to decarbonization.

The monoethanolamine (MEA) segment accounted for a dominant 38.6% market share in 2024. Known for its strong affinity to carbon dioxide and its ability to form stable carbamate compounds, MEA remains a cornerstone of chemical absorption systems. Its reliability, operational consistency, and widespread availability have made it a go-to choice for post-combustion capture, particularly in legacy energy infrastructure.

Post-combustion capture technologies led the market with a 53.1% share in 2024, largely because of their seamless integration into existing systems. Industries favor this method as it allows them to reduce carbon emissions with minimal disruption to operations. Supported by decades of pilot testing, commercial projects, and engineering improvements, post-combustion capture continues to be the most practical and widely adopted solution.

The United States Amine-Based Carbon Capture Market was valued at USD 190.4 million in 2024. Federal incentives like tax credits, coupled with flexible state-level regulations, have made the U.S. a leading market for carbon capture innovation. Fast-track permitting for Class VI wells by the Environmental Protection Agency and delegated state authorities has shortened project timelines and boosted investor confidence, further accelerating deployment.

Key industry players include Toshiba Energy Systems & Solutions, Linde PLC, Mitsubishi Heavy Industries, Fluor Corporation, Koch-Glitsch, Shell CANSOLV, BASF SE, Pentair, Carbon Clean, and GEA Group. These companies are focusing on enhancing solvent regeneration efficiency, launching modular carbon capture units, and scaling up pilot projects into full-scale commercial operations. Their efforts are helping to drive down costs and improve the scalability of next-generation amine systems across a wide range of industrial applications.

Table of Contents

Chapter 1 Methodology & Scope

• 1.1 Market scope & definition
• 1.2 Base estimates & calculations
• 1.3 Forecast calculation
• 1.4 Data sources
  • 1.4.1 Primary
  • 1.4.2 Secondary
    • 1.4.2.1 Paid sources
    • 1.4.2.2 Public sources
• 1.5 Primary research and validation
  • 1.5.1 Primary sources
  • 1.5.2 Data mining sources

Chapter 2 Executive Summary

• 2.1 Industry synopsis, 2021-2034

Chapter 3 Industry Insights

• 3.1 Industry ecosystem analysis
  • 3.1.1 Key manufacturers
  • 3.1.2 Distributors
  • 3.1.3 Profit margins across the industry
  • 3.1.4 Supply disruptions
• 3.2 Trump administration tariffs
  • 3.2.1 Impact on trade
    • 3.2.1.1 Trade volume disruptions
    • 3.2.1.2 Retaliatory measures
  • 3.2.2 Impact on the industry
    • 3.2.2.1 Supply-side impact (raw materials)
      • 3.2.2.1.1 Price volatility in key materials
      • 3.2.2.1.2 Supply chain restructuring
      • 3.2.2.1.3 Production cost implications
    • 3.2.2.2 Demand-side impact (selling price)
      • 3.2.2.2.1 Price transmission to end markets
      • 3.2.2.2.2 Market share dynamics
      • 3.2.2.2.3 Consumer response patterns
  • 3.2.3 Key companies impacted
  • 3.2.4 Strategic Industry Responses
    • 3.2.4.1 Supply Chain Reconfiguration
    • 3.2.4.2 Pricing and Product Strategies
    • 3.2.4.3 Policy Engagement
  • 3.2.5 Outlook and Future Considerations
• 3.3 Trade statistics (HS Code)
  • 3.3.1 Major Exporting Countries
  • 3.3.2 Major Importing Countries
• 3.4 Profit margin analysis
• 3.5 Key news & initiatives
• 3.6 Regulatory landscape
• 3.7 Impact forces
  • 3.7.1 Growth drivers
    • 3.7.1.1 Increasing deployment of monoethanolamine in post-combustion CO2 capture in coal-fired power plants
    • 3.7.1.2 Technological improvements in methyldiethanolamine blends for natural gas sweetening
    • 3.7.1.3 Rising investments in direct air capture (DAC) using amine-functionalized solid sorbents
  • 3.7.2 Industry pitfalls & challenges
    • 3.7.2.1 High energy penalty and operational costs associated with solvent regeneration
    • 3.7.2.2 Corrosiveness of certain amines, requiring expensive materials for plant infrastructure
• 3.8 Growth potential analysis
• 3.9 Porter's analysis
• 3.10 PESTEL analysis

Chapter 4 Competitive Landscape, 2024

• 4.1 Introduction
• 4.2 Company market share analysis
• 4.3 Competitive positioning matrix
• 4.4 Strategic outlook matrix

Chapter 5 Market Estimates and Forecast, By Type of Amines, 2021–2034 (USD Million) (Kilo Tons)

• 5.1 Key trends
• 5.2 Monoethanolamine
• 5.3 Diethanolamine
• 5.4 Methyldiethanolamine
• 5.5 Triethanol amine
• 5.6 Others

Chapter 6 Market Estimates and Forecast, By Application, 2021–2034 (USD Million) (Kilo Tons)

• 6.1 Key trends
• 6.2 Post-combustion capture
• 6.3 Pre-combustion capture
• 6.4 Direct air capture
• 6.5 Others

Chapter 7 Market Estimates and Forecast, By Region, 2021–2034 (USD Million) (Kilo Tons)

• 7.1 Key trends
• 7.2 North America
  • 7.2.1 U.S.
  • 7.2.2 Canada
• 7.3 Europe
  • 7.3.1 Germany
  • 7.3.2 UK
  • 7.3.3 France
  • 7.3.4 Spain
  • 7.3.5 Italy
  • 7.3.6 Netherlands
• 7.4 Asia Pacific
  • 7.4.1 China
  • 7.4.2 India
  • 7.4.3 Japan
  • 7.4.4 Australia
  • 7.4.5 South Korea
• 7.5 Latin America
  • 7.5.1 Brazil
  • 7.5.2 Mexico
  • 7.5.3 Argentina
• 7.6 Middle East and Africa
  • 7.6.1 Saudi Arabia
  • 7.6.2 South Africa
  • 7.6.3 UAE

Chapter 8 Company Profiles

• 8.1 BASF SE
• 8.2 Carbon Clean
• 8.3 Fluor Corporation
• 8.4 GEA Group
• 8.5 Koch-Glitsch
• 8.6 Linde PLC
• 8.7 Mitsubishi Heavy Industries
• 8.8 Pentair
• 8.9 Shell CANSOLV
• 8.10 Toshiba Energy Systems & Solutions