Effects of SO2, H2O and O2 in coal-fired flue gas on solid CO2 adsorbents: Mechanisms and modification strategies

LIU Yuxin; XU Yufeng; JING Jieying

doi:10.12434/j.issn.2097-2547.20250479

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Effects of SO₂, H₂O and O₂ in coal-fired flue gas on solid CO₂ adsorbents: Mechanisms and modification strategies

更新时间：2026-04-17

- Effects of SO₂, H₂O and O₂ in coal-fired flue gas on solid CO₂ adsorbents: Mechanisms and modification strategies
- Pages: 1-15(2026)
- 作者机构：
  
  1.太原理工大学省部共建煤基能源清洁高效利用国家重点实验室，山西太原 030024
  2.太原理工大学化学与化工学院，山西太原 030024
- 作者简介：
- 基金信息：
- DOI：10.12434/j.issn.2097-2547.20250479
  CLC： TQ424
- Received：18 December 2025，
  
  Revised：2025-12-25，
  
  Online First：15 April 2026，
- 稿件说明：
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刘雨欣,徐玉凤,荆洁颖.燃煤烟气中SO₂、H₂O和O₂对固体CO₂吸附剂的影响机制与改性策略[J].低碳化学与化工,

LIU Yuxin,XU Yufeng,JING Jieying.Effects of SO₂, H₂O and O₂ in coal-fired flue gas on solid CO₂ adsorbents: Mechanisms and modification strategies[J].Low-Carbon Chemistry and Chemical Engineering,
刘雨欣,徐玉凤,荆洁颖.燃煤烟气中SO₂、H₂O和O₂对固体CO₂吸附剂的影响机制与改性策略[J].低碳化学与化工, DOI：10.12434/j.issn.2097-2547.20250479.

LIU Yuxin,XU Yufeng,JING Jieying.Effects of SO₂, H₂O and O₂ in coal-fired flue gas on solid CO₂ adsorbents: Mechanisms and modification strategies[J].Low-Carbon Chemistry and Chemical Engineering, DOI：10.12434/j.issn.2097-2547.20250479.

摘要

燃煤烟气CO

捕集是实现碳减排的关键环节，高效稳定的固体CO

吸附剂是该环节的核心。然而，实际烟气中的杂质气体（如H

O、O

和SO

）会劣化吸附剂结构并降低其CO

吸附性能，这对CO

捕集技术的应用产生了不利影响。阐述了SO

、H

O和O

对典型固体CO

吸附剂（如CaO基、MgO基和固体胺吸附剂）吸附性能的影响，并总结了针对性改性策略。目前研究多关注单一杂质的影响，同时改性方法存在成本过高和工艺复杂等问题。未来研究可考虑多种杂质共存的影响，并优化吸附剂改性策略，以期开发兼具高吸附性能和高稳定性，并能适应复杂条件的CO

吸附剂。

Abstract

capture from coal-fired flue gas is a critical step in achieving carbon emissions reduction

and highly efficient and stable solid CO

adsorbents are central to this process. However

impurity gas

es (such as H

and SO

) in actual flue gas can degrade the adsorbent structure and reduce its CO

adsorption performance

which adversely affects the application of CO

capture technologies. Effects of SO

O and O

on adsorption performance of typical solid CO

adsorbents (such as CaO-based

MgO-based and solid amine adsorbents) were described and targeted modification strategies were summarized. Current research often focuses on the effect of a single impurity

while existing modification methods suffer from issues such as high costs and complex processes. Future research can consider the effects of multiple coexisting impurities and optimize adsorbent modification strategies to develop CO

adsorbents that combine high adsorption performances and stabilities while being capable of operating under complex conditions.

关键词

Keywords

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