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Enhanced Ultramicropore of Biomass‐Derived Porous Carbon for Efficient and Low‐Energy <scp>CO</scp> <sub>2</sub> Capture: Integration of Adsorption and Solar Desorption

Pengcheng GuoResearch Institute of Automobile Parts Technology Hunan Institute of Technology Hengyang 421002 ChinaRuiqi XueCollege of Mechanical and Intelligent Manufacturing Central South University of Forestry and Technology Changsha 410004 ChinaQiao ZouCollege of Mechanical and Intelligent Manufacturing Central South University of Forestry and Technology Changsha 410004 ChinaXiancheng MaCollege of Mechanical and Intelligent Manufacturing Central South University of Forestry and Technology Changsha 410004 ChinaChangqing SuHunan Key Laboratory of Carbon Neutrality and Intelligent Energy, School of Resources &amp; Environment Hunan University of Technology and Business Changsha 410205 ChinaZheng ZengSchool of Energy Science and Engineering Central South University Changsha 410083 ChinaLiqing LiSchool of Energy Science and Engineering Central South University Changsha 410083 China
2025en
ABI

Аннотация

Biomass‐derived carbon for CO 2 capture is significant for reducing carbon emissions and recovering C1 resources, contributing to zero‐carbon goals. However, developing biomass‐based porous carbon with high CO 2 capture while reducing regeneration energy consumption remains challenging. This study leverages the tunable pore structure and photothermal properties of biomass‐based carbon, integrating adsorption and solar‐driven desorption for efficient, low‐energy CO 2 capture. Specifically, mechanical compaction increased the ultramicropore volume of the porous carbon by 25%, leading to a corresponding 25% enhancement in CO 2 adsorption capacity. Theoretical calculations and correlation analyses further elucidated that ultramicropore volume, nitrogen doping, and oxygen doping play significant roles in CO 2 adsorption. Under one‐sun illumination, the surface temperature of the prepared porous carbon rapidly rose to 57.1 °C within 6 min and stabilized around 71.0 °C, resulting in a regeneration efficiency of 75%. These findings provide valuable theoretical and practical insights for the development of high‐efficiency, low‐energy CO 2 capture technologies.

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