From Capture to Conversion: Advances and Challenges in Integrated CO2 Capture and Utilization for Industrial Decarbonization
回収から転換へ:産業脱炭素化のための統合的二酸化炭素回収・利用技術の進展と課題 (AI 翻訳)
Peng Bian, Qinchen Meng, Xianyin Yu, Jinou Han, Zhichen Zeng, Xudong Wang
🤖 gxceed AI 要約
日本語
本レビューは、統合的二酸化炭素回収・利用(ICCU)技術の最新動向を体系的にまとめたものである。従来の分離型プロセスと比較して、ICCUは中間工程を削減し、炭素利用効率を向上させる。溶媒吸収と固体吸着の2つの回収経路、および逆水性ガスシフト、メタン化、ドライリフォーミングなどの変換経路を詳述し、光触媒や非熱プラズマなどの非在来型エネルギー支援戦略の可能性を探る。鉄鋼、セメント、発電などの炭素集約型産業への適用を展望し、マルチスケール機構の解明、高性能デュアルファンクション材料の開発、システム統合の最適化が重要と結論づける。
English
This review systematically summarizes recent progress in Integrated CO2 Capture and Utilization (ICCU) technology, which reduces intermediate steps and improves carbon utilization efficiency compared to conventional separated processes. It covers solvent-based absorption and solid-sorbent adsorption as capture routes, and conversion pathways such as reverse water-gas shift, methanation, and dry reforming. Non-conventional energy-assisted strategies (photocatalysis, electrocatalysis, non-thermal plasma, microwave) are examined, along with applications in carbon-intensive industries (steel, cement, power). The review highlights the importance of elucidating multiscale synergistic mechanisms, developing high-performance dual-function materials, and optimizing system integration.
Unofficial AI-generated summary based on the public title and abstract. Not an official translation.
📝 gxceed 編集解説 — Why this matters
日本のGX文脈において
日本は鉄鋼・化学など炭素集約型産業の脱炭素化が急務であり、ICCU技術は既存インフラとの親和性が高い。特に、国内で研究が進む固体吸着材や非在来型エネルギー利用(プラズマ、マイクロ波)の知見と整合する点で、本レビューは日本のCCUSロードマップに示唆を与える。
In the global GX context
ICCU represents a paradigm shift from linear capture-storage to circular capture-utilization, aligning with global trends in circular carbon economy. This review provides a comprehensive technical baseline for industries and policymakers evaluating next-generation CCUS pathways, particularly relevant to ISSB/TCFD-aligned transition planning and industrial decarbonization commitments.
👥 読者別の含意
🔬研究者:The review identifies key scientific challenges (multiscale synergy, dual-function materials) and emerging energy-assisted strategies, offering a roadmap for future research on integrated carbon capture and conversion.
🏢実務担当者:Companies in steel, cement, and power sectors can evaluate the technology readiness and integration potential of ICCU for reducing energy penalty and operational costs in carbon management.
🏛政策担当者:The paper underscores the need for supporting R&D in integrated capture-utilization systems, which could lower the cost of industrial decarbonization and enable circular carbon economy policies.
📄 Abstract(原文)
Amid growing pressure to reduce carbon emissions, carbon capture, utilization, and storage (CCUS) has become an important pathway toward deep decarbonization. However, the conventional separated “capture–release–conversion” process suffers from high energy consumption and system complexity, which severely limits its large-scale application. Integrated CO2 Capture and Utilization (ICCU), which enables the capture, activation, and conversion of CO2 within a single system, has attracted widespread attention because it can effectively reduce intermediate energy-intensive steps and improve carbon utilization efficiency. This review systematically summarizes recent progress in ICCU technology, with particular emphasis on reaction mechanisms and interfacial coupling characteristics. The performance features of solvent-based chemical absorption and solid-sorbent adsorption, two widely studied capture routes, are summarized, and typical integrated conversion pathways, including reverse water–gas shift, methanation, and dry reforming of methane, are discussed. On this basis, the roles of non-conventional energy-assisted strategies, such as photocatalysis, electrocatalysis, non-thermal plasma, and microwave irradiation, in expanding ICCU systems are further examined, together with their system-level coupling potential in carbon-intensive industries such as steel, cement, and power generation. Finally, the key scientific issues and engineering challenges currently facing ICCU are analyzed from the perspectives of fundamental mechanisms, material design, and system engineering, and future development directions are proposed. This review highlights that elucidating multiscale synergistic mechanisms, developing high-performance dual-function materials, and optimizing system integration are crucial to promoting the industrial application of ICCU technology.
🔗 Provenance — このレコードを発見したソース
- crossref https://doi.org/10.3390/separations13060179first seen 2026-06-19 05:31:09
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