二氧化碳 (CO2) 化學合成的技術成長機會

化學公司尋求顛覆性技術來減少二氧化碳排放並創造新的收益來源

隨著對氣候變遷的擔憂變得越來越緊迫，全球關注永續性，包括減少碳足跡和使用綠色化學物質。隨著該地區的化學品製造商尋求新的方法來最大限度地減少其設施中的二氧化碳（CO2）排放，對二氧化碳作為原料的需求也在增加。

本研究將重點放在將捕獲的二氧化碳轉化為商品、精細和特種化學品的方法，並將重點放在能夠從二氧化碳合成化學品的各種技術。它還檢驗了業界為提高這些技術的商業性潛力所做的努力，並確定了將二氧化碳轉化為化學品的七種關鍵方法：熱轉化、電化學轉化、催化共聚和酶轉化、礦化、等離子體催化和光輔助轉化。本研究確定了推動和抑制這些技術採用的因素，並概述了該領域的專利。還提供詳細的區域分析，包括有關各種化學產品中二氧化碳使用的趨勢、研發（R&D）、相關人員計劃和成本分析的資訊。也發現該產業變化帶來的成長機會，供市場相關人員和利害關係者利用。

目錄

改變二氧化碳化學合成方法

• 為什麼成長越來越困難？
• The Strategic Imperative 8（TM）
• 二氧化碳對化學合成產業的關鍵策略要務的影響

生態系統

成長機會分析

• 產業現況：CO2排放增加，對CO2原料的需求增加
• 工業CO2使用需求現況及未來
• 二氧化碳儲存挑戰與能源效率需求

成長要素

• 生長促進因子
• 成長抑制因素

CO2 化學合成的區域趨勢

• 碳捕獲、利用和儲存（CCUS）展望：北美
• 產業舉措：北美
• CCUS 展望：亞太地區
• 產業舉措：亞太地區
• CCUS 展望：歐洲
• 產業舉措：歐洲
• CCUS 視角：拉丁美洲、中東和非洲（LAMEA）
• 產業計劃：LAMEA

技術分析

• 將二氧化碳轉化為化學品的方法
• 各種CO2化學轉換技術比較分析
• 熱轉化：化學生產的節能途徑
• 電化學轉化：將二氧化碳轉化為有價值化學品的最有前途的方法
• 催化共聚：一種從二氧化碳中提取特種化學品的方法
• 酶促轉化：由於高選擇性和產量而成為一種有前途的方法
• 礦化：透過直接空氣捕獲消除各種工業來源二氧化碳排放的經濟有效的方法
• 等離子體催化劑：
• 光輔助轉換：一個受到複雜性和低選擇性挑戰的過程

產業努力實現二氧化碳化學合成

• 產業舉措：處於商業化早期階段的Start-Ups
• 產業舉措：學術界對電化學方法的關注
• 優先考慮技術進步的公共資金的主要活動
• 促進商業化的​​主要私人融資活動
• 主要合作夥伴及合資企業
• 對二氧化碳衍生化學品的創業投資快速成長：展望

專利情況

• 中國在CO2化學合成相關專利方面佔優勢
• 學術界引領二氧化碳化學合成研究
• 按轉化方法、生產的化學產品分類的重點領域

CO2 化學合成的成長機會

• 成長機會1：提高二氧化碳化學合成效率的催化劑
• 成長機會2：利用二氧化碳合成化學品的混合系統
• 成長機會3：全球標準監理實現經濟效益

附錄

• 技術成熟度（TRL）：描述

最佳實踐認識

Frost Radar

下一步

Chemical companies are looking for disruptive technologies to reduce CO2 emissions and create additional revenue streams

With climate change concerns becoming increasingly urgent, there is a growing global emphasis on sustainability, including a focus on reducing carbon footprints and using green chemicals. While chemical manufacturers across regions are looking for new ways to minimize carbon dioxide (CO2) emissions from their facilities, there is also rising demand for CO2 as a raw material.

This study covers the various technologies that allow the synthesis of chemicals from CO2, focusing on approaches that transform captured CO2 into commodity, fine, and specialty chemicals. It examines the industry efforts to increase the commercial potential of these technologies, identifying 7 pivotal approaches to converting CO2 into chemicals: thermal conversion, electrochemical conversion, catalytic copolymerization, enzymatic conversion, mineralization, plasma catalysis, and photo-assisted conversion. The study highlights the factors driving and restraining the adoption of these technologies and offers an overview of the patents in this domain. It provides a detailed regional analysis, covering information on trends, research and development (R&D) efforts, and stakeholder initiatives, along with a cost analysis of CO2 utilization for various chemical products. The growth opportunities emerging from the shifts in this space have also been identified for market players and stakeholders to leverage.

Table of Contents

Transformation in the Synthesis of Chemicals from CO2

• Why Is It Increasingly Difficult to Grow?
• The Strategic Imperative 8™
• The Impact of the Top 3 Strategic Imperatives on the Synthesis of Chemicals from CO2 Industry

Ecosystem

• Research Methodology
• Research Scope
• Segmentation
• Comparison between the Production of a Chemical from CO2 and the Conventional Production of the Same Chemical
• Conversion Applications of CO2

Growth Opportunity Analysis

• Industrial Landscape: Rising CO2 Emissions and Growing Demand for CO2 as a Raw Material
• Present and Future CO2 Utilization Demand across Industries
• CO2 Storage Challenges and Energy-efficiency Needs

Growth Generator

• Growth Drivers
• Growth Restraints

Regional Trends for the Synthesis of Chemicals from CO2

• Carbon Capture, Utilization, and Storage (CCUS) Outlook: North America
• Industry Initiatives: North America
• CCUS Outlook: Asia-Pacific
• Industry Initiatives: Asia-Pacific
• CCUS Outlook: Europe
• Industry Initiatives: Europe
• CCUS Outlook: Latin America, the Middle East, and Africa (LAMEA)
• Industry Initiatives: LAMEA

Technology Analysis

• Approaches for the Conversion of CO2 to Chemicals
• Comparative Analysis of Different CO2 to Chemicals Conversion Technologies
• Thermal Conversion: An Energy-efficient Path for Chemical Production
• Electrochemical Conversion: Most Promising Approach for Converting CO2 into Valuable Chemicals
• Catalytic Copolymerization: An Approach that Extracts Specialty Chemicals from CO2
• Enzymatic Conversion: A Promising Approach due to High Selectivity and Yield
• Mineralization: A Cost-effective way to Eliminate CO2 Emission from Various Industrial Sources through Direct Air Capture
• Plasma Catalysis: A Process that
• Photo-assisted Conversion: A Process Challenged by High Complexity and Low Selectivity

Industry Efforts Enabling the Synthesis of Chemicals from CO2

• Industry Initiatives: Start-ups Entering Early Stages of Commercialization
• Industry Initiatives: Academia Focus on the Electrochemical Approach
• Key Public Funding Activities Prioritizing Technology Advancement
• Key Private Funding Activities to Expedite Commercialization
• Key Partnerships and Joint Ventures
• Venture Capital Surge in CO2-derived Chemicals: An Outlook

Patent Landscape

• China Dominates the Patents Space for the Synthesis of Chemicals from CO2
• Academia Drives Research on the Synthesis of Chemicals from CO2
• Key Focus Areas of Top Assignees by Conversion Approach and Chemical Produced

Growth Opportunity Universe for the Synthesis of Chemicals from CO2

• Growth Opportunity 1: Catalysts to Improve the Efficiency of the Synthesis of Chemicals from CO2
• Growth Opportunity 2: Hybrid Systems with Higher Energy Efficiency to Synthesize Chemicals from CO2
• Growth Opportunity 3: Standardized Global Regulations for Achieving Economic Benefits

Appendix

• Technology Readiness Level (TRL): Explanation

Best Practices Recognition

• Best Practices Recognition

Frost Radar

• Frost Radar

Next Steps

• Benefits and Impacts of Growth Opportunities
• Next Steps
• Take the Next Step
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