二氧化碳的捕集、固定与利用的研究进展

doi:10.11962/1006-4990.2019-0307

Abstract

Abstract:

In the face of the crisis caused by the deteriorating greenhouse effect,countries have agreed to take measures to re-duce carbon dioxide emissions.China has promised to peak its carbon emissions around 2030.However,carbon dioxide emis-sions control and capture（CCS） remains a major global environmental challenge.Carbon dioxide sequestration has been the direction and focus of researchers,who also attempts to introduce a new method,i.e.carbon dioxide utilization to achieve more thorough and efficient carbon capture and sequestration.Some studies have pointed out that mineralization is a new direction of carbon dioxide utilization,and its advantages of environmental protection and low cost have attracted people′s attention.Carbon capture and utilization by seawater has promoted the further research of carbon dioxide mineralization under another threat of freshwater shortage,which not only achieves the fixed utilization of CO₂,but also solves the problem of seawater pre-treatment or brine waste utilization from the desalination plant.The research progress of carbon dioxide capture,fixation and utilization methods in recent years was summarized.Through the analysis of the advantages and disadvantages of various methods,it was found that the concept of carbon utilization has injected new vitality into CCS.

Key words: carbon dioxide, CCS, utilization, mineralization, seawater

CLC Number:

TQ116.3

Wang Jianhang,Zhao Yingying,Li Jiahui,Yuan Junsheng. Research progress of carbon dioxide capture,fixation and utilization[J]. Inorganic Chemicals Industry, 2020, 52(4): 12-17.

Figures/Tables 1

References 46

[1]	Kopp R E, Kemp A C, Horton B P , et al. Temperature-driven global sea-level variability in the Common Era[J]. Proceedings of the Na-tional Academy of Sciences, 2016,113(11):1434-1441.
[2]	Kemp A C, Horton B P, Donnelly J P , et al. Climate related sea-level variations over the past two millennia[J]. Proceedings of the Natio-nal Academy of Sciences, 2011,108(27):11017-11022. doi: 10.1073/pnas.1015619108 pmid: 21690367
[3]	Liu Shuqiao . State of Climate in 2017—Extreme weather and high im-pacts[DB/OL]. WMO, 2018-03-22..
[4]	Morvova M, Morva I, Hanic F . Single step removal of CO₂ incorpora-ting CO₂ and nitrogen fixation from gas phase in electric dischar-ge [C]∥Eliasson B,Riemer P,Wokaun A.4th International Con-ference on Greenhouse Gas Control Technologies (GHGT-4).Amsterdam:International Journal of Greenhouse Gas Control, 1999: 137-142.
[5]	Fiaschi D, Pellegrini G . Capture of CO₂ from exhausts emissions with a solution of potassium phosphate [C]∥Frangopoulos C A,Rakopo-ulos C D,Tsatsaronis G.19th International Conference on Efficien-cy,Cost,Optimization,Simulation and Environmental Impact of Energy Systems(ECOS 2006).Aghia Pelagia:ENERGY, 2006.
[6]	Greenberg S E . Creating a sequestration capacity building and kno-wledge sharing program[J]. Energy Procedia, 2013,37:7291-7298. doi: 10.1016/j.egypro.2013.06.667
[7]	Bui M, Adjiman C S, Bardow A , et al. Carbon capture and stora-ge(CCS):the way forward[J]. Energy & Environmental Science, 2018,11(Part A):1062-1176. doi: 10.1016/j.jenvman.2018.08.009 pmid: 30114572
[8]	王升 . CCUS技术推广为何遇冷[EB/OL].人民网, 2018-08-27. .
[9]	Li Ping, Pan Shuyuan . Challenges and perspectives on carbon fixa-tion and utilization technologies:an overview[J]. Aerosol and AirQuality Research, 2016,16:1327-1328.
[10]	Bennaceur K, Gielen D, Kerr T , et al. CO₂ capture and storage:a key carbon abatement option[M]. Paris:International Energy Agen-cy, 2008.
[11]	Kumar A, Madden D G, Lusi M , et al. Direct air capture of CO₂ by physisorbent materials[J]. Angewandte Chemie, 2016,127(48):14580-14585. doi: 10.1002/ange.201506952
[12]	Evgenia M, Solomom B, Paul S , et al. CO₂ capture and storage(CCS)cost reduction via infrastructure right-sizing[J]. Chemical Engi-neering Research and Design, 2017,119:130-139.
[13]	方陵生 . 为二氧化碳排放算笔帐[J].世界科学, 2007(11):17-18.
[14]	Ramaraj R, Tsai D W, Chen P H . Carbon dioxide fixation of fresh-water microalgae growth on natural water medium[J]. Ecological Engineering, 2015,75(78):86-92. doi: 10.1016/j.ecoleng.2014.11.033
[15]	Acien Fernandez F G, Gonzalea-Lopez C V, Fernandez-Sevilla J M , et al. Conversion of CO₂ into biomass by microalgae:how reali-stic a contribution may it be to significant CO₂ removal?[J]. Appli-ed Microbiology & Biotechnology, 2012,96(3):577-586. doi: 10.1007/s00253-012-4362-z pmid: 22923096
[16]	Judd S, Lj V D B, Shurair M , et al. Algal remediation of CO and nu-trient discharges:A review[J]. Water Research, 2015,87:356-366. doi: 10.1016/j.watres.2015.08.021 pmid: 26451978
[17]	Hsueh H T, Chu H, Yu S T . A batch study on the bio-fixation of carbon dioxide in the absorbed solution from a chemical wet scru-bber by hot spring and marine algae[J]. Chemosphere, 2007,66(5):878-886. doi: 10.1016/j.chemosphere.2006.06.022 pmid: 16860839
[18]	Chang W T, Lee M, Den W . Simultaneous carbon capture,biomass production,and diary wastewater purification by spirulina maxima photobioreaction[J]. Industrial & Engineering Chemistry Resear-ch, 2013,52(5):2046-2055.
[19]	Cavenati S, Grande C A . Adsorption equilibrium of methane,car-bon dioxide,and nitrogen on zeolite 13X at high pressures[J]. Jo-urnal of Chemical & Engineering Data, 2004,49(4):1095-1101.
[20]	Armandi M, Garrone E, Carlos O A , et al. Thermodynamics of car-bon dioxide adsorption on the protonic zeolite H-ZSM-5[J]. Ch-emphyschem, 2009,10(18):3316-3319. doi: 10.1002/cphc.200900561 pmid: 19882617
[21]	Martunus H Z, Wiheeb A D, Kim J , et al. In situ carbon dioxide capture and fixation from a hot flue gas[J]. International Journal of Greenhouse Gas Control, 2012,6:179-188. doi: 10.1016/j.ijggc.2011.11.012
[22]	Arean C O, Delgado M R, Bulanek R , et al. Combined microcalori-metric and IR spectroscopic study on carbon dioxide adsorption in H-MCM-22[J]. Applied Surface Science, 2014,316:532-536. doi: 10.1016/j.apsusc.2014.08.036
[23]	Zheng X Y, Diao Y F, He B S, et al. Carbon dioxide recovery from flue gases by ammonia scrubbing [C]∥Gale J,Kaya Y.6th Interna-tional Conference on Greenhouse Gas Control Technologies.Kyoto:Greenhouse Gas Control Technologies, 2003: 193-197.
[24]	宿辉, 崔琳 . 二氧化碳的吸收方法及机理研究[J]. 环境科学与管理, 2006,31(8):79-81.
[25]	Xiao S, Liu H, Gao H , et al. Kinetics and mechanism study of homo-geneous reaction of CO₂,and blends of diethanolamine and mo-noethanolamine using the stopped-flow technique[J]. Chemical Engineering Journal, 2017,316:592-600.
[26]	Park S, Min J, Lee M G , et al. Characteristics of CO₂ fixation by chemical conversion to carbonate salts[J]. Chemical EngineeringJournal, 2013,231:287-293.
[27]	Kang D, Park S, Jo H , et al. Carbon fixation using calcium oxide by an aqueous approach at moderate conditions[J]. Chemical Engi-neering Journal, 2014,248:200-207.
[28]	Park S, Bang J H, Song K , et al. Barium carbonate precipitation as a method to fix and utilize carbon dioxide[J]. Chemical Engineering Journal, 2016,284:1251-1258. doi: 10.1016/j.cej.2015.09.059
[29]	Chen P C, Shi W, Du R , et al. Crystallization kinetics of barium carbonate crystals in a lab-scale bubble-column scrubber[J]. Jour-nal of the Taiwan Institute of Chemical Engineers, 2014,45(5):2418-2426.
[30]	Kang D, Lee M G, Jo H , et al. Carbon capture and utilization using industrial wastewater under ambient conditions[J]. Chemical En-gineering Journal, 2017,308:1073-1080.
[31]	Zhang S, Chen Y, Li F , et al. Fixation and conversion of CO₂ using ionic liquids[J]. Catalysis Today, 2006,115(1/2/3/4):61-69.
[32]	Huang Y, Cui G, Zhao Y , et al. Preorganization and cooperation for highly efficient and reversible capture of low-concentration CO₂ by ionic liquids[J]. Angewandte Chemie International Edition, 2017,56(43):13293-13297. doi: 10.1002/anie.201706280 pmid: 28857376
[33]	Xu Y J . CO₂ absorption behavior of azole-based protic ionic liquids:Influence of the alkalinity and physicochemical properties[J]. Jo-urnal of CO₂ Utilization, 2017,19:1-8.
[34]	周维卫, 传秀云, 周述慧 . 蛇纹石及其固体废弃物固定CO₂的研究现状[J]. 矿物学报, 2010(s1):179-180.
[35]	Bobicki E R, Liu Q, Xu Z , et al. Carbon capture and storage using alkaline industrial wastes[J]. Progress in Energy & Combustion Science, 2012,38(2):302-320.
[36]	Arias B, Alonso M, Abanades C . CO₂ capture by calcium looping at relevant conditions for cement plants:experimental testing in a 30 kWth Pilot Plant[J]. Industrial & Engineering Chemistry Re-search, 2017,56(10):2634-2640.
[37]	Ebranhimi A, Saffari M, Hong Y , et al. Mineral sequestration of CO₂ using saprolite mine tailings in the presence of alkaline industrial wastes[J]. Journal of Cleaner Production, 2018,188:686-697.
[38]	莫淳, 廖文杰, 梁斌 , 等. 工业固废活化钾长石-CO₂ 矿化提钾的生命周期碳排放与成本评价[J]. 化工学报, 2017,68(6):2501-2509.
[39]	谢和平, 谢凌志, 王昱飞 , 等. 全球二氧化碳减排不应是CCS,应是CCU[J]. 四川大学学报, 2012,44:1-5.
[40]	Giwa A, Dufour V, Al M F , et al. Brine management methods:recent innovations and current status[J]. Desalination, 2017,407:1-23.
[41]	Wang W, Hu M, Zheng Y , et al. CO₂ fixation in Ca ²+-/Mg ²+-rich aqueous solutions through enhanced carbonate precipitation [J]. Ind.Eng.Chem.Res., 2011,50(13):8333-8339.
[42]	Zhao Y, Yuan J, Zhang J , et al. A different approach for seawater decalcification pretreatment using carbon dioxide as precipita-tor[J]. Desalination, 2013,322:151-158. doi: 10.1016/j.desal.2013.04.032
[43]	Zhao Y, Cao H, Xie Y , et al. Mechanism studies of a CO₂ partici-pant softening pretreatment process for seawater desalination[J]. Desalination, 2016,393:166-173.
[44]	Zhao Y, Zhang Y, Liu J , et al. Trash to treasure:Seawater pretreat-ment by CO₂ mineral carbonation using brine pretreatment waste of soda ash plant as alkali source[J]. Desalination, 2017,407:85-92. doi: 10.1016/j.desal.2016.12.018
[45]	Jose-Luis G M, Ammar E, Jennie M , et al. Conceptual design of a CO₂ capture and utilisation process based on calcium and magne-sium rich brines[J]. Journal of CO₂ Utilization, 2018,27:161-169.
[46]	Zhao Y, Wu M, Yuan J , et al. Thorough conversion of CO₂ through two-step accelerated mineral carbonation in the MgCl₂-CaCl₂-H₂O system[J]. Separation and Purification Technology, 2019,210:343-354.

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Research progress of carbon dioxide capture,fixation and utilization

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