|本期目录/Table of Contents|

[1]唐 航,杨文平,杨明科,等.固体多孔CO2吸附材料研究进展[J].武汉工程大学学报,2026,48(03):270-278.[doi:10.19843/j.cnki.CN42-1779/TQ.202410021]
 TANG Hang,YANG Wenping,YANG Mingke,et al.Research progress on solid porous materials for CO2 adsorption[J].Journal of Wuhan Institute of Technology,2026,48(03):270-278.[doi:10.19843/j.cnki.CN42-1779/TQ.202410021]
点击复制

固体多孔CO2吸附材料研究进展
(/HTML)

《武汉工程大学学报》[ISSN:1674-2869/CN:42-1779/TQ]

卷:
48
期数:
2026年03期
页码:
270-278
栏目:
现代大化工
出版日期:
2026-06-30

文章信息/Info

Title:
Research progress on solid porous materials for CO2 adsorption
文章编号:
1674 - 2869(2026)03 - 0270 - 09
作者:
唐 航1杨文平2杨明科3沈 陟*1纪匀峰1宋 浩1马 骏1沈喜洲1
1.武汉工程大学化工与制药学院,绿色化工过程教育部重点实验室(武汉工程大学),
湖北 武汉 430205;
2.湖北省化学工业研究设计院,湖北 武汉 430070;
3. 中石化石油化工科学研究有限公司,北京 100083
Author(s):
1. School of Chemical Engineering and Pharmacy, Key Laboratory for Green Chemical Process of Ministry of Education
(Wuhan Institute of Technology),Wuhan 430205, China;
2. Hubei Research and Design Institute of Chemical Industry, Wuhan 430070, China;
3. Sinopec Research Institute of Petroleum Processing Co., Ltd., Beijing 100083, China
关键词:
Keywords:
分类号:
TQ424
DOI:
10.19843/j.cnki.CN42-1779/TQ.202410021
文献标志码:
A
摘要:
CO2的捕集、封存和利用(CCUS)技术被认为是实现“碳达峰”和“碳中和”的有效手段之一。CO2的捕集技术主要有胺吸收法、固体吸附法和膜分离法3种途径。固体吸附法由于具有低成本、无腐蚀、低再生能耗等优点而被认为是目前较有前景的一种CO2捕获方法。综述了固体吸附法吸附材料的研究进展:多孔无机材料来源广泛、稳定性好,但吸附选择性低;无机-有机杂化材料结构可调、吸附容量高,但水热稳定性差;多孔有机材料(COFs)比表面积大、结构规则、吸附性能可调、选择性高,但合成复杂、成本较高。此外还展望了固体吸附材料在CO2捕集的应用前景,旨在为固体多孔CO2吸附材料的开发提供助力。
Abstract:
Carbon capture, utilization, and storage (CCUS) technology is considered one of the effective approaches to achieving carbon peak and carbon neutrality. The main methods for CO2 capture include amine absorption, solid adsorption, and membrane separation. Solid adsorption is currently considered as one of the most promising CO2 capture techniques due to its advantages such as low cost, non-corrosiveness and low regeneration energy consumption. In this study, we reviewed the research progress of solid adsorbent materials for CO2 capture, with a focus on three categories: porous inorganic materials, inorganic-organic hybrid materials, and porous organic materials. Porous inorganic materials are inexpensive, readily available, and exhibit good stability, but suffer from low adsorption selectivity. Inorganic-organic hybrid materials possess tunable structures and high CO2 adsorption capacity, yet their hydrothermal stability remains a limitation. Porous organic materials feature large specific surface areas, well-defined structures, tunable adsorption performance, and high selectivity; however, their synthesis is complex and the associated costs are high. The prospects for the application of solid adsorbent materials in CO2 capture were also discussed, aiming to provide insights and support for the development of advanced porous CO2 adsorbents.

参考文献/References:

[ 1 ] PARKINSON B, BALCOMBE P, SPRIRS J F, et al. Levelized cost of CO2 mitigation from hydrogen production routes [J]. Energy & Environmental Science, 2019, 12(1): 19-40.
[ 2 ] OLIVIER J, JANSSENS-MAENHOUT G, MUNT-EAN M, et al. Trends in Global CO2 emissions: 2015 report [R]. The Hague:PBL Netherlands Environmental Assessment Agency,2015.
[ 3 ] 高慧, 杨艳, 刘知鑫. 二氧化碳大规模脱除与利用技术综述[J]. 世界石油工业, 2021, 28(6): 42-52.
[ 4 ] RHODES C J. The 2015 Paris climate change conference: COP 21 [J]. Science Progress, 2016, 99(1): 97-104.
[ 5 ] WILBERFORCE T, BAROUTAJI A, SOUDAN B, et al. Outlook of carbon capture technology and challenges [J]. Science of the Total Environment, 2019, 657: 56-72.
[ 6 ] OCHEDI F O, LIU Y X, ADEWUYI Y G. State-of-the-art review on capture of CO2 using adsorbents prepared from waste materials [J]. Process Safety and Environmental Protection, 2020, 139: 1-25.
[ 7 ] BOYD P G, CHIDAMBARAM A, GARCIA-DIEZ E, et al. Data-driven design of metal-organic frameworks for wet flue gas CO2 capture [J]. Nature, 2019, 576(7786): 253-256.
[ 8 ] OZKAN M, AKHAVI A A, COLEY W C, et al. Progress in carbon dioxide capture materials for deep decarbonization [J]. Chem, 2022, 8(1): 141-173.
[ 9 ] YAMADA H. Comparison of solvation effects on CO2 capture with aqueous amine solutions and amine-functionalized ionic liquids [J]. The Journal of Physical Chemistry B,2016,120(40):10563-10568.
[10] XU X G, WOOD C D. A Highly Tunable approach to enhance CO2 capture with liquid alkali/amines [J]. Environmental Science & Technology,2018,52(18): 10874-10882.
[11] HU X Y, LIU L B, LUO X, et al. A review of N-functionalized solid adsorbents for post-combustion CO2 capture [J]. Applied Energy,2020,260: 114244.
[12] KRISHNA R, van BATEN J M. A comparison of the CO2 capture characteristics of zeolites and metal-organic frameworks [J]. Separation and Purification Technology, 2012, 87: 120-126.
[13] HAN Y, WINSTON HO W S. Polymeric membranes for CO2 separation and capture [J]. Journal of Membrane Science, 2021, 628: 119244.
[14] GEYER F, SCHONECKER C, BUTT H J, et al. Enhancing CO2 capture using robust superomniphobic membranes [J]. Advanced Materials, 2017, 29(5): 1603524.
[15] WANG Y H, ZHOU Y, ZHANG X R, et al. SPEEK membranes by incorporation of NaY zeolite for CO2/N2 separation [J]. Separation and Purification Technology, 2021, 275: 119189.
[16] OLUKUNLE O I, LEHMAN D C, SALAMOVA A, et al. Temporal trends of dechlorane plus in air and precipitation around the north american great lakes [J]. Science of the Total Environment, 2018, 642: 537-542.
[17] EL HADRI N, QUANG D V, GOETHEER E L V, et al. Aqueous amine solution characterization for post-combustion CO2 capture process [J]. Applied Energy, 2017, 185(2): 1433-1449.
[18] GUO M Z, LIANG S K, LIU J T, et al. Epoxide-functionalization of grafted tetraethylenepentamine on the framework of an acrylate copolymer as a CO2 sorbent with long cycle stability [J]. ACS Sustainable Chemistry & Engineering, 2020, 8(9): 3853-3864.
[19] WU S F, YAN T, KUAI Z H, et al. Thermal conduc-tivity enhancement on phase change materials for thermal energy storage: a review [J]. Energy Storage Materials, 2020, 25: 251-295.
[20] 樊瑞军. 多孔炭的制备、改性及其在CO2吸附中的应用[D]. 大连: 大连理工大学, 2013.
[21] LI J R, SCULLEY J, ZHOU H C. Metal-organic frame-works for separations [J]. Chemical Reviews, 2012, 112(2): 869-932.
[22] 王斓懿, 于学华, 赵震. 无机多孔材料的合成及其在环境催化领域的应用[J]. 物理化学学报, 2017, 33(12): 2359-2376.
[23] 周冬兰, 廖丹, 张文展, 等. 金属-有机骨架材料改性研究进展[J]. 化工新型材料, 2023, 51(12): 27-30, 38.
[24] 崔永君. 煤对CH4, N2, CO2及多组分气体吸附的研究[D]. 北京:煤炭科学研究总院, 2003.
[25] 刘大中, 王锦. 物理吸附与化学吸附[J]. 山东轻工业学院学报(自然科学版), 1999(2): 24-27.
[26] 高赫. 煤和生物质制备活性焦及CO2吸附性能探究[D]. 济南: 山东大学, 2023.
[27] RAO C N R, NATARAJAN S, VAIDHYANATHAN R. Metal carboxylates with open architectures [J]. Angewandte Chemie International Edition, 2004, 43(12): 1466-1496.
[28] COLVIN V L, SCHLAMP M C, ALIVISATOS A P. Light-emitting diodes made from cadmium selenide nanocrystals and a semiconducting polymer [J]. Nature, 1994, 370(6488): 354-357.
[29] TANEV P T, PINNAVAIA T J. A neutral templating route to mesoporous molecular sieves [J]. Science, 1995, 267(5199): 865-867.
[30] ZHENG H Q, GAO F F, VALTCHEV V. Nanosized inorganic porous materials: fabrication, modification and application [J]. Journal of Materials Chemistry A, 2016, 4(43): 16756-16770.
[31] MASHHADIMOSLEM H, GHAEMI A, MALEKI A, et al. Enhancement of oxygen adsorption using biomass-based oxidized porous carbon [J]. Journal of Environmental Chemical Engineering, 2023, 11(2): 109300.
[32] WANG Q, LI Y R, YU Z C, et al. Highly porous carbon derived from hydrothermal-pyrolysis synergistic carbonization of biomass for enhanced CO2 capture [J]. Colloids and Surfaces A: Physicochemical and Engineering Aspects, 2023, 673: 131787.
[33] ISMAIL I S, SINGH G, SMITH P, et al. Oxygen functionalized porous activated biocarbons with high surface area derived from grape marc for enhanced capture of CO2 at elevated-pressure [J]. Carbon, 2020, 160: 113-124.
[34] CHE H X, WEI G T, FAN Z D, et al. Super facile one-step synthesis of sugarcane bagasse derived N-doped porous biochar for adsorption of ciprofloxacin [J]. Journal of Environmental Management, 2023, 335: 117566.
[35] SHEN F, WANG Y, LI L Y, et al. Porous carbonaceous materials from hydrothermal carbonization and KOH activation of corn stover for highly efficient CO2 capture [J]. Chemical Engineering Communications, 2018, 205(4): 423-431.
[36] BAI J L, HUANG J M, YU Q Y, et al. One-pot synthesis of self S-doped porous carbon for efficient CO2 adsorption [J]. Fuel Processing Technology, 2023, 244: 107700.
[37] BAI J L, HUANG J M, YU Q Y, et al. N-doped porous carbon derived from macadamia nut shell for CO2 adsorption [J]. Fuel Processing Technology, 2023, 249: 107854.
[38] LI W T, HUANG T, HUANG W Z, et al. Prepara-tion of nitrogen-doped activated carbon from bio-oil residue for efficient CO2 adsorption [J]. Industrial Crops and Products, 2024, 210: 118097.
[39] LI Z L, ZHOU Y L, YAN W, et al. Cost-effective monolithic hierarchical carbon cryogels with ntrogen doping and high-performance mechanical properties for CO2 capture [J]. ACS Applied Materials & Interfaces, 2020,12(19):21748-21760.
[40] MEHRA P, PAUL A. Decoding carbon-based materials, properties for high CO2 capture and selectivity [J]. ACS Omega, 2022, 7(38): 34538-34546.
[41] SERAFIN J, OUZZINE M, CRUZ O F, et al. Conversion of fruit waste-derived biomass to highly microporous activated carbon for enhanced CO2 capture [J]. Waste Management, 2021, 136:273-282.
[42] GUO T X, ZHANG Y H, GENG Y H, et al. Surface oxidation modification of nitrogen doping biochar for enhancing CO2 adsorption [J]. Industrial Crops and Products, 2023, 206: 117582.
[43] MA X C, YANG Y H, WU Q D, et al. Underlying mechanism of CO2 uptake onto biomass-based porous carbons: do adsorbents capture CO2 chiefly through narrow micropores[J]. Fuel, 2020, 282: 118727.
[44] de SOUZA L K C, GONCALVES A A S, QUEIROZ L S, et al. Utilization of acai stone biomass for the sustainable production of nanoporous carbon for CO2 capture [J]. Sustainable Materials and Technologies, 2020, 25: 00168.
[45] JADHAV P D, CHATTI R V, BINIWALE R B, et al. Monoethanol amine modified zeolite 13X for CO2 adsorption at different temperatures [J]. Energy & Fuels, 2007, 21(6): 3555-3559.
[46] MIYAMOTO M, ONO S, KUSUKAMI K, et al. High water tolerance of a core-shell-structured zeolite for CO2 adsorptive separation under wet conditions [J]. ChemSusChem, 2018, 11(11): 1756-1760.
[47] BOER D G, ASGAR POUR Z, POLI S, et al. ZSM-5/Silicalite-1 core-shell beads as CO2 adsorbents with increased hydrophobicity [J]. Materials Today Chemistry, 2023, 32: 101621.
[48] TEMEREV V L, VEDYAGIN A A, AFONASENKO T N, et al. Effect of Ag loading onthe adsorption/desorption properties of ZSM-5 towards toluene [J]. Reaction Kinetics, Mechanisms and Catalysis, 2016, 119(2): 629-640.
[49] SUN M Z, GU Q F, HANIF A, et al. Transition metal cation-exchanged SSZ-13 zeolites for CO2 capture and separation from N2 [J]. Chemical Engineering Journal, 2019, 370: 1450-1458.
[50] 乐垚. 二氧化硅的形貌调控及其吸附性能研究[D]. 武汉: 武汉理工大学, 2013.
[51] TANEV P T, PINNAVAIA T J. Biomimetic templa-ting of porous lamellar silicas by vesicular surfactant assemblies [J]. Science,1996,271(5253):1267-1269.
[52] RYOO R, JUN S. Improvement of hydrothermal stability of MCM-41 using salt effects during the crystallization process [J]. The Journal of Physical Chemistry B, 1997, 101(3): 317-320.
[53] RAVUTSOV M, MITREV Y, SHESTAKOVA P, et al. CO2 adsorption on modified mesoporous silicas: the role of the adsorption sites [J]. Nanomaterials, 2021, 11(11): 2831.
[54] THOMMES M. Physisorption of gases, with special reference to the evaluation of surface area and pore size distribution (IUPAC technical report) [J]. Chemistry International, 2016, 38(1): 25.
[55] ZELENAK V, SKRINSKA M, SIPERSTEIN F R, et al. Phase evolution during one-pot synthesis of amine modified mesoporous silica materials: preparation, properties, carbon dioxide adsorption [J]. Applied Surface Science, 2019, 476: 886-896.
[56] TUMURBAATAR O, POPOVA M, MITOVA, et al. Engineering of silica mesoporous materials for CO2 adsorption [J]. Materials, 2023, 16(11): 4179.
[57] CORMA A, GARCIA H, LLABRES I, et al Engineering metal organic frameworks for heterogeneous catalysis [J]. Chemical Reviews, 2010, 110(8): 4606-4655.
[58] MEEK S T, GREATHOUSE J A, ALLENDORF M D. Metal-organic frameworks: a rapidly growing class of versatile nanoporous materials [J]. Advanced Materials, 2011, 23(2): 249-267.
[59] FRACAROLI A M, FURUKAWA H, SUZUKI M, et al. Metal-organic frameworks with precisely designed interior for carbon dioxide capture in the presence of water [J]. Journal of the American Chemical Society, 2014, 136(25): 8863-8866.
[60] NUGENT P, BELMABKHOUT Y, BURD S D, et al. Porous materials with optimal adsorption thermodynamics and kinetics for CO2 separation [J]. Nature, 2013, 495(7439): 80-84.
[61] LIN Y C, YAN Q J, KONG C L, et al. Polyethylenei-mine incorporated metal-organic frameworks adsorbent for highly selective CO2 capture [J]. Scientific Reports, 2013, 3: 1859.
[62] MASON J A, SUMIDA K, HERM Z R, et al. Evaluating metal-organic frameworks for post-combustion carbon dioxide capture via temperature swing adsorption [J]. Energy & Environmental Science, 2011, 4(8): 3030-3040.
[63] SI X L, ZHANG J, LI F, et al. Adjustable structure transition and improved gases (H2, CO2) adsorption property of metal-organic framework MIL-53 by encapsulation of BNHx [J]. Dalton Transactions, 2012, 41(11): 3119-3122.
[64] BOURRELLY S, LLEWELLYN P L, SERRE C, et al. Different adsorption behaviors of methane and carbon dioxide in the isotypic nanoporous metal terephthalates MIL-53 and MIL-47 [J]. Journal of the American Chemical Society, 2005, 127(39): 13519-13521.
[65] QIAN X K, SUN F X, SUN J, et al. Imparting surface hydrophobicity to metal-organic frameworks using a facile solution-immersion process to enhance water stability for CO2 capture [J]. Nanoscale, 2017, 9(5): 2003-2008.
[66] ZHANG W, HU Y L, GE J, et al. A facile and general coating approach to moisture/water-resistant metal-organic frameworks with intact porosity [J]. Journal of the American Chemical Society, 2014, 136(49): 16978-16981.
[67] 马亚娟. 纳米TiO2表面微孔设计促进CO2吸附与光催化还原[D]. 武汉: 华中科技大学, 2021.
[68] 聂莉娟. 基于聚乙烯亚胺改性和接枝的多孔材料制备及其对CO2吸附性能研究[D]. 北京: 北京化工大学, 2019.
[69] BAGHERI A R, ARAMESH N, SHER F, et al. Covalent organic frameworks as robust materials for mitigation of environmental pollutants [J]. Chemosphere, 2021, 270: 129523.
[70] DONG J Q, HAN X, LIU Y, et al. Metal-covalent organic frameworks (MCOFs): a bridge between metal-organic frameworks and covalent organic frameworks [J]. Angewandte Chemie International Edition, 2020, 59(33): 13722-13733.
[71] 赵尚. 共价有机材料的合成、表征及CO2吸附应用[D]. 大连: 大连理工大学, 2016.
[72] ZENG Y F, ZOU R Q, ZHAO Y L. Covalent organic frameworks for CO2 capture [J]. Advanced Materials, 2016, 28(15): 2855-2873.
[73] CHEN J, LI H, ZHONG M M, et al. Tuning the surface polarity of microporous organic polymers for CO2 capture [J]. Chemistry-An Asian Journal, 2017, 12(17): 2291-2298.
[74] OZDEMIR J, MOSLEH I, ABOLHASSANI M, et al. Covalent organic frameworks for the capture, fixation, or reduction of CO2 [J]. Frontiers in Energy Research, 2019, 7: 77.
[75] PATEL H A, HYUN J S, PARK J, et al. Unprece-dented high-temperature CO2 selectivity in N2-phobic nanoporous covalent organic polymers [J]. Nature Communications, 2013, 4: 1357.


相似文献/References:

备注/Memo

备注/Memo:
收稿日期:2024-10-28
基金项目:湖北省自然科学基金(2025AFCIII)
作者简介:唐 航,硕士研究生。Email: tanghang2062@163.com
*通信作者:沈 陟,博士, 副教授。Email:shenzhi20121111@163.com
引文格式:唐航,杨文平,沈陟,等. 固体多孔CO2吸附材料研究进展[J]. 武汉工程大学学报,2026,48(3):270-278.
更新日期/Last Update: 2026-06-26