Recent progress of amine modified sorbents for capturing CO2 from flue gas

doi:10.1016/j.cjche.2018.04.009

Abstract

Abstract: Under the Paris agreement, China has committed to reducing CO₂ emissions by 60%-65% per unit of GDP by 2030. Since CO₂ emissions from coal-fired power plants currently account for over 30% of the total carbon emissions in China, it will be necessary to mitigate at least some of these emissions to achieve this goal. Studies by the International Energy Agency (IEA) indicate CCS technology has the potential to contribute 14% of global emission reductions, followed by 40% of higher energy efficiency and 35% of renewable energy, which is considered as the most promising technology to significantly reduce carbon emissions for current coal-fired power plants. Moreover, the announcement of a Chinese national carbon trading market in late 2017 signals an opportunity for the commercial deployment of CO₂ capture technologies.
Currently, the only commercially demonstrated technology for post-combustion CO₂ capture technology from power plants is solvent-based absorption. While commercially viable, the costs of deploying this technology are high. This has motivated efforts to develop more affordable alternatives, including advanced solvents, membranes, and sorbent capture systems. Of these approaches, advanced solvents have received the most attention in terms of research and demonstration. In contrast, sorbent capture technology has less attention, despite its potential for much lower energy consumption due to the absence of water in the sorbent. This paper reviews recent progress in the development of sorbent materials modified by amine functionalities with an emphasis on material characterization methods and the effects of operating conditions on performance. The main problems and challenges that need to be overcome to improve the competitiveness of sorbent-based capture technologies are discussed.

Key words: CO₂ sorbent, Amine, Flue gas, CO₂ adsorption, CO₂ regeneration

摘要： Under the Paris agreement, China has committed to reducing CO₂ emissions by 60%-65% per unit of GDP by 2030. Since CO₂ emissions from coal-fired power plants currently account for over 30% of the total carbon emissions in China, it will be necessary to mitigate at least some of these emissions to achieve this goal. Studies by the International Energy Agency (IEA) indicate CCS technology has the potential to contribute 14% of global emission reductions, followed by 40% of higher energy efficiency and 35% of renewable energy, which is considered as the most promising technology to significantly reduce carbon emissions for current coal-fired power plants. Moreover, the announcement of a Chinese national carbon trading market in late 2017 signals an opportunity for the commercial deployment of CO₂ capture technologies.
Currently, the only commercially demonstrated technology for post-combustion CO₂ capture technology from power plants is solvent-based absorption. While commercially viable, the costs of deploying this technology are high. This has motivated efforts to develop more affordable alternatives, including advanced solvents, membranes, and sorbent capture systems. Of these approaches, advanced solvents have received the most attention in terms of research and demonstration. In contrast, sorbent capture technology has less attention, despite its potential for much lower energy consumption due to the absence of water in the sorbent. This paper reviews recent progress in the development of sorbent materials modified by amine functionalities with an emphasis on material characterization methods and the effects of operating conditions on performance. The main problems and challenges that need to be overcome to improve the competitiveness of sorbent-based capture technologies are discussed.

关键词: CO₂ sorbent, Amine, Flue gas, CO₂ adsorption, CO₂ regeneration

Xinglei Zhao, Qian Cui, Baodeng Wang, Xueliang Yan, Surinder Singh, Feng Zhang, Xing Gao, Yonglong Li. Recent progress of amine modified sorbents for capturing CO₂ from flue gas[J]. Chin.J.Chem.Eng., 2018, 26(11): 2292-2302.

References

[1] China ratifies Paris climate change agreement ahead of G20.[EB/OL], https://www.theguardian.com/world/2016/sep/03/.

[2] C.M. White, B.R. Strazisar, E.J. Granite, J.S. Hoffman, H.W. Pennline, Separation and capture of CO₂ from large stationary sources and sequestration in geological formations-Coalbeds and deep saline aquifers, J. Air Waste Manage. Assoc. 53(2003) 645-715.

[3] D. Aaron, C. Tsouris, Separation of CO₂ from flue gas:A review, Sep. Sci. Technol. 40(2011) 321-348.

[4] Q. Wang, J. Luo, Z. Zhong, A. Borgna, CO₂ capture by solid adsorbents and their applications:Current status and new trends, Energy Environ. Sci. 4(2010) 42-55.

[5] B. Dutcher, M. Fan, A.G. Russell, Amine-based CO₂ capture technology development from the beginning of 2013-A review, ACS Appl. Mater. Interfaces 7(2015) 2137-2148.

[6] W. Xie, X. Ji, T. Fan, X. Feng, X. Lu, CO₂ uptake behavior of supported tetraethylenepentamine sorbents, Energy Fuel 30(2016) 5083-5091.

[7] Q. Xiao, J. Wen, Y. Guo, J. Hu, J. Wang, F. Zhang, Synthesis, carbonization, and CO₂ adsorption properties of phloroglucinol-melamine-formaldehyde polymeric nanofibers, Ind. Eng. Chem. Res. 55(2016) 12667-12674.

[8] Q. Wang, Y. Liu, J. Chen, Z. Du, J. Mi, Control of uniform and interconnected macroporous structure in polyHIPE for enhanced CO₂ adsorption/desorption kinetics, Environ. Sci. Technol. 50(2016) 7879-7888.

[9] M. Gray, Y. Soong, K. Champagne, H. Pennline, J. Baltrus, R. Stevens Jr., R. Khatri, S. Chuang, T. Filburn, Improved immobilized carbon dioxide capture sorbents, Fuel Process. Technol. 86(2005) 1449-1455.

[10] L. Wang, M.A. Lei, A. Wang, Q. Liu, T. Zhang, CO₂ adsorption on SBA-15 modified by aminosilane, Chin. J. Catal. 28(2007) 805-810.

[11] X. Yan, L. Zhang, Y. Zhang, K. Qiao, Z. Yan, S. Komarneni, Amine-modified mesocellular silica foams for CO₂ capture, Chem. Eng. J. 168(2011) 918-924.

[12] R. Serna-Guerrero, A. Sayari, Modeling adsorption of CO₂ on amine-functionalized mesoporous silica. 2:Kinetics and breakthrough curves, Chem. Eng. J. 161(2010) 182-190.

[13] F. Su, C. Lu, S. Kuo, W. Zeng, Adsorption of CO₂ on amine-functionalized Y-type zeolites, Energy Fuel 24(2010) 1441-1448.

[14] R.S. Franchi, P.J.E. Harlick, A. Sayari, Applications of pore-expanded mesoporous silica. 2. Development of a high-capacity, water-tolerant adsorbent for CO₂, Ind. Eng. Chem. Res. 44(2005) 8007-8013.

[15] G. Hao, W. Li, D. Qian, A. Lu, Rapid synthesis of nitrogen-doped porous carbon monolith for CO₂ capture, Adv. Mater. 22(2010) 853-857.

[16] W. Shen, W. Fan, Nitrogen-containing porous carbons:Synthesis and application, J. Mater. Chem. A 1(2013) 999-1013.

[17] M. Sevilla, A.B. Fuertes, Sustainable porous carbons with a superior performance for CO₂ capture, Energy Environ. Sci. 4(2011) 1765-1771.

[18] J. Gu, W. Kim, Y. Hwang, S. Huh, Template-free synthesis of N-doped porous carbons and their gas sorption properties, Carbon 56(2013) 208-217.

[19] J. Gong, B. Michalkiewicz, X. Chen, E. Mijowska, J. Liu, Z. Jiang, X. Wen, T. Tang, Sustainable conversion of mixed plastics into porous carbon nanosheets with high performances in uptake of carbon dioxide and storage of hydrogen, ACS Sustain. Chem. Eng. 2(2014) 2837-2844.

[20] P. Moloney, C. Huffman, O. Gorelik, P. Nikolaev, S. Arepalli, R. Allada, M. Springer, L. Yowell, Materials for Space Applications, Materials Research Society, Warrendale, PA 851, 200559-64.

[21] F. Su, C. Lu, W. Cnen, H. Bai, J.F. Hwang, Capture of CO₂ from flue gas via multiwalled carbon nanotubes, Sci. Total Environ. 407(2009) 3017-3023.

[22] T.M. Mcdonald, W.R.L. Lee, J.A. Mason, M.B. Wiers, C.S. Hong, J.R. Long, Capture of carbon dioxide from air and flue gas in the alkylamine-appended metal-organic framework mmen-Mg₂(dobpdc), J. Am. Chem. Soc. 134(2012) 7056-7065.

[23] R.W. Flaig, T.M. Osborn Popp, A.M. Fracaroli, E.A. Kapustin, M.J. Kalmutzki, R.M. Altamimi, F. Fathieh, J.A. Reimer, O.M. Yaghi, The chemistry of CO₂ capture in an amine-functionalized metal-organic framework under dry and humid conditions, J. Am. Chem. Soc. 139(2017) 12125-12128.

[24] Q. Wang, H. Ma, J. Chen, Z. Du, J. Mi, Interfacial control of polyHIPE with nano-TiO₂ particles and polyethylenimine toward actual application in CO₂ capture, J. Environ. Chem. Eng. 5(2017) 2807-2814.

[25] S.D. Kenarsari, D. Yang, G. Jiang, S. Zhang, J. Wang, A.G. Russell, Q. Wei, M. Fan, Review of recent advances in carbon dioxide separation and capture, RSC Adv. 3(2013) 22739-22773.

[26] D.M. D'Alessandro, B. Smit, J.R. Long, Carbon dioxide capture:Prospects for new materials, Angew. Chem. Int. Ed. 49(2010) 6058-6082.

[27] M.C. Duke, B. Ladewig, S. Smart, V. Rudolph, J.C.D.D. Costa, Assessment of postcombustion carbon capture technologies for power generation, Front. Chem. Eng. China 4(2010) 184-195.

[28] A.S. Bhown, B.C. Freeman, Analysis and status of post-combustion carbon dioxide capture technologies, Environ. Sci. Technol. 45(2011) 8624-8632.

[29] A.M. Kierzkowska, P. Roberta, C.R. Muller, CaO-based CO₂ sorbents:From fundamentals to the development of new, highly effective materials, ChemSusChem 6(2013) 1130-1148.

[30] Y. Liu, Q. Ye, M. Shen, J. Shi, J. Chen, H. Pan, Y. Shi, Carbon dioxide capture by functionalized solid amine sorbents with simulated flue gas conditions, Environ. Sci. Technol. 45(2011) 5710-5716.

[31] M.G. Plaza, C. Pevida, A. Arenillas, F. Rubiera, J.J. Pis, CO₂ capture by adsorption with nitrogen enriched carbons, Fuel 86(2007) 2204-2212.

[32] A. Samanta, A. Zhao, G.K. Shimizu, P. Sarkar, R. Gupta, Post-combustion CO₂ capture using solid sorbents:A review, Ind. Eng. Chem. Res. 51(2011) 1438-1463.

[33] W. Li, S. Choi, J.H. Drese, M. Hornbostel, G. Krishnan, P.M. Eisenberger, C.W. Jones, Steam-stripping for regeneration of supported amine-based CO₂ adsorbents, ChemSusChem 3(2010) 899-903.

[34] W.J. Son, J.S. Choi, W.S. Ahn, Adsorptive removal of carbon dioxide using polyethyleneimine-loaded mesoporous silica materials, Microporous Mesoporous Mater. 113(2008) 31-40.

[35] X.C. Xu, C.S. Song, J.M. Andresen, B.G. Miller, A.W. Scaroni, Novel polyethyleniminemodified mesoporous molecular sieve of mcm-41 type as high-capacity adsorbent for CO₂ capture, Energy Fuel 16(2002) 1463-1469.

[36] X.C. Xu, C.S. Song, J.M. Andresen, B.G. Miller, A.W. Scaroni, Preparation and characterization of novel CO₂"molecular basket" adsorbents based on polymer-modified mesoporous molecular sieve MCM-41, Microporous Mesoporous Mater. 62(2003) 29-45.

[37] X.C. Xu, C.S. Song, B.G. Miller, A.W. Scaroni, Influence of moisture on CO₂ separation from gas mixture by a nanoporous adsorbent based on polyethylenimine-modified molecular sieve MCM-41, Ind. Eng. Chem. Res. 44(2005) 8113-8119.

[38] X.W. Liu, L. Zhou, X. Fu, Y. Sun, W. Su, Y.P. Zhou, Adsorption and regeneration study of the mesoporous adsorbent SBA-15 adapted to the capture/separation of CO₂ and CH₄, Chem. Eng. Sci. 62(2007) 1101-1110.

[39] X.X. Wang, V. Schwartz, J.C. Clark, X.L. Ma, S.H. Overbury, X.C. Xu, C.S. Song, Infrared study of CO₂ sorption over ‘molecular basket’ sorbent consisting of polyethylenimine-modified mesoporous molecular sieve, J. Phys. Chem. C 113(2009) 7260-7268.

[40] S. Kim, J. Ida, V.V. Guliants, J.Y.S. Lin, Tailoring pore properties of MCM-48 silica for selective adsorption of CO₂, J. Phys. Chem. B 109(2005) 6287-6293.

[41] P.J.E. Harlick, A. Sayari, Applications of pore-expanded mesoporous silicas. 3. Triamine silane grafting for enhanced CO₂ adsorption, Ind. Eng. Chem. Res. 45(2006) 3248-3255.

[42] R.A. Khatri, S.S.C. Chuang, Y. Soong, M. Gray, Thermal and chemical stability of regenerable solid amine sorbent for CO₂ capture, Energy Fuel 20(2006) 1514-1520.

[43] A.A. Alhwaige, H. Ishida, S. Qutubuddin, Carbon aerogels with excellent CO₂ adsorption capacity synthesized from clay-reinforced biobased chitosan-polybenzoxazine nanocomposites, ACS Sustain. Chem. Eng. 4(2016) 1286-1295.

[44] G.P. Hao, W.C. Li, D. Qian, G.H. Wang, W.P. Zhang, T. Zhang, A.Q. Wang, F. Schuth, H.J. Bongard, A.H. Lu, Structurally designed synthesis of mechanically stable poly-(benzoxazine-co-resol)-based porous carbon monoliths and their application as high-performance CO₂ capture sorbents, J. Am. Chem. Soc. 133(2011) 11378-11388.

[45] Q. Ye, J. Jiang, C. Wang, Y. Liu, H. Pan, Y. Shi, Adsorption of low-concentration carbon dioxide on amine-modified carbon nanotubes at ambient temperature, Energy Fuel 26(2012) 2497-2504.

[46] Y. Belmabkhout, R. Serna-Guerrero, A. Sayari, Adsorption of CO₂-containing gas mixtures over amine-bearing pore-expanded MCM-41 silica:Application for gas purification, Ind. Eng. Chem. Res. 49(2010) 359-365.

[47] Z. Chen, S. Deng, H. Wei, B. Wang, J. Huang, G. Yu, Polyethylenimine-impregnated resin for high CO₂ adsorption:An efficient adsorbent for CO₂ capture from simulated flue gas and ambient air, ACS Appl. Mater. Interfaces 5(2013) 6937-6945.

[48] M.E. Pinto, S.H. Pang, C.W. Jones, Adsorption microcalorimetry of CO₂ in confined aminopolymers, Langmuir 33(2017) 117-124.

[49] R. Kishor, A.K. Ghoshal, Amine-modified mesoporous silica for CO₂ adsorption:The role of structural parameters, Ind. Eng. Chem. Res. 56(2017) 6078-6087.

[50] L. Ma, R. Bai, G. Hu, R. Chen, X. Hu, W. Dai, H.F.M. Dacosta, M. Fan, Capturing CO₂ with amine-impregnated titanium oxides, Energy Fuel 27(2013) 5433-5439.

[51] F.Q. Liu, L. Wang, Z.G. Huang, C.Q. Li, W. Li, R.X. Li, W.H. Li, Amine-tethered sorbents based on three-dimensional macroporous silica for CO₂ capture from simulated flue gas and air, ACS Appl. Mater. Interfaces 6(2014) 4371-4381.

[52] W.H. Daly, D. Poche, The preparation of n-carboxyanhydrides of alpha-amino-acids using bis(trichloromethyl) carbonate, Tetrahedron Lett. 29(1988) 5859-5862.

[53] M.L. Pinto, L. Mafra, J.M. Guil, J. Pires, J. Rocha, Adsorption and activation of CO₂ by amine-modified nanoporous materials studied by solid-state NMR and ¹³CO₂ adsorption, Chem. Mater. 23(2011) 1387-1395.

[54] F.Q. Liu, L. Wang, Z.G. Huang, C.Q. Li, W. Li, R.X. Li, W.H. Li, Amine-tethered adsorbents based on three-dimensional macroporous silica for CO₂ capture from simulated flue gas and air, ACS Appl. Mater. Interfaces 6(2014) 4371-4381.

[55] B.J. Maring, P.A. Webley, A new simplified pressure/vacuum swing adsorption model for rapid adsorbent screening for CO₂ capture applications, Int. J. Greenhouse Gas Control 15(2013) 16-31.

[56] P. Li, B. Ge, S. Zhang, S. Chen, Q. Zhang, Y. Zhao, CO₂ capture by polyethyleniminemodified fibrous adsorbent, Langmuir 24(2008) 6567-6574.

[57] M.W. Hahn, J. Jelic, E. Berger, K. Reuter, A. Jentys, J.A. Lercher, Role of amine functionality for CO₂ chemisorption on silica, J. Phys. Chem. B 120(2016) 1988-1995.

[58] R. Numaguchi, J. Fujiki, H. Yamada, Firoz, A. Chowdhury, K. Kida, K. Goto, T. Okumura, K. Yoshizawa, K. Yogo, Development of post-combustion CO₂ capture system using amine-impregnated solid sorbent, Energy Procedia 114(2017) 2304-2312.

[59] A.A. Govar, A.D. Ebner, J.A. Ritter, Effect of H₂O vapor on the adsorption and desorption behavior of CO₂ in a solid amine sorbent, Energy Fuel 30(2016) 10653-10660.

[60] P.J.E. Harlick, A. Sayari, Applications of pore-expanded mesoporous silica. 5. Triamine grafted material with exceptional CO₂ dynamic and equilibrium adsorption performance, Ind. Eng. Chem. Res. 46(2007) 446-458.

[61] R. Serna-Guerrero, E. Da'na, A. Sayari, New insights into the interactions of CO₂ with amine-functionalized silica, Ind. Eng. Chem. Res. 47(2008) 9406-9412.

[62] A. Danon, P.C. Star, E. Weitz, FTIR study of CO₂ adsorption on amine-grafted SBA-15:Elucidation of adsorbed species, J. Phys. Chem. C 115(2011) 11540-11549.

[63] C.T. Hung, C.F. Yang, J.S. Lin, S.J. Huang, Y.C. Chang, S.B. Liu, Capture of carbon dioxide by polyamine-immobilized mesostructured silica:A solid-state NMR study, Microporous Mesoporous Mater. 238(2017) 2-13.

[64] Z. Bacsik, N. Ahlsten, A. Ziadi, G. Zhao, A.E. Garcia-Bennett, B. Martin-Matute, N. Hedin, Mechanisms and kinetics for sorption of CO₂ on bicontinuous mesoporous silica modified with n-propylamine, Langmuir 27(2011) 11118-11128.

[65] W.C. Wilfong, C.S. Srikanth, S.S.C. Chaung, In situ ATR and DRIFTS studies of the nature of adsorbed CO₂ on tetraethylenepentamine films, ACS Appl. Mater. Interfaces 6(2014) 13617-13626.

[66] Q. Liu, J. Shi, Q. Wang, M. Tao, Y. He, Y. Shi, Carbon dioxide capture with polyethylenimine-functionalized industrial-grade multiwalled carbon nanotubes, Ind. Eng. Chem. Res. 53(2014) 17468-17475.

[67] T.C. Dos Santos, S. Bourrelly, P.L. Llewellyn, J.W. Carneiro, C.M. Ronconi, Adsorption of CO₂ on amine-functionalised MCM-41:Experimental and theoretical studies, Phys. Chem. Chem. Phys. 17(2015) 11095-11102.

[68] S. Sutanto, J.W. Dijkstra, J.A.Z. Pieterse, J. Boon, P. Hauwert, D.W.F. Brilman, CO₂ removal from biogas with supported amine sorbents:First technical evaluation based on experimental data, Sep. Purif. Technol. 184(2017) 12-25.

[69] J.C. Hicks, C.W. Jones, Controlling the density of amine sites on silica surfaces using benzyl spacers, Langmuir 22(2006) 2676-2681.

[70] J.C. Hicks, R. Dabestani, A.C.B. Iii, C.W. Jones, Spacing and site isolation of amine groups in 3-aminopropyl-grafted silica materials:The role of protecting groups, Chem. Mater. 18(2006) 5022-5032.

[71] J.D. Bass, A. Katz, Bifunctional surface imprinting of silica:Thermolytic synthesis and characterization of discrete thiol-amine functional group pairs, Chem. Mater. 18(2006) 1611-1620.

[72] Y. Wang, T. Du, Y. Song, S. Che, X. Fang, L. Zhou, Amine-functionalized mesoporous ZSM-5 zeolite adsorbents for carbon dioxide capture, Solid State Sci. 73(2017) 27-35.

[73] G. Zhang, P. Zhao, Y. Xu, Development of amine-functionalized hierarchically porous silica for CO₂ capture, J. Ind. Eng. Chem. 54(2017) 59-68.

[74] C. Chen, W.J. Son, K.S. You, J.W. Ahn, W.S. Ahn, Carbon dioxide capture using amine-impregnated HMS having textural mesoporosity, Chem. Eng. J. 161(2010) 46-52.

[75] S. Choi, M.L. Gray, C.W. Jones, Amine-tethered solid adsorbents coupling high adsorption capacity and regenerability for CO₂ capture from ambient air, ChemSusChem 4(2011) 628-635.

[76] W.R.A. Jr, J.R. Kitchin, Evaluation of a primary amine-functionalized ion-exchange resin for CO₂ capture, Ind. Eng. Chem. Res. 51(2012) 6907-6915.

[77] D. Lee, Y. Jin, N. Jung, J. Lee, J. Lee, Y.S. Jeong, S. Jeon, Gravimetric analysis of the adsorption and desorption of CO₂ on amine-functionalized mesoporous silica mounted on a microcantilever array, Environ. Sci. Technol. 45(2011) 5704-5709.

[78] M.W. Hahn, M. Steib, A. Jentys, J.A. Lercher, Mechanism and kinetics of CO₂ adsorption on surface bonded amines, J. Phys. Chem. C 119(2015) 4126-4135.

[79] Z. Zhang, B. Wang, Q. Sun, X. Ma, Enhancing sorption performance of solid amine sorbents for CO₂ capture by additives, Energy Procedia 37(2013) 205-210.

[80] S.A. Didas, M.A. Sakwa-Novak, G.S. Foo, C. Sievers, C.W. Jones, Effect of amine surface coverage on the co-adsorption of CO₂ and water:Spectral deconvolution of adsorbed species, J. Phys. Chem. Lett. 5(2014) 4194-4200.

[81] H. Zhang, A. Goeppert, G.A. Olah, G.K.S. Prakash, Remarkable effect of moisture on the CO₂ adsorption of nano-silica supported linear and branched polyethylenimine, J. CO₂ Util. 19(2017) 91-99.

[82] F. Rezaei, R.P. Lively, Y. Labreche, G. Chen, Y. Fan, W.J. Koros, C.W. Jones, Aminosilane-grafted polymer/silica hollow fiber adsorbents for CO₂ capture from flue gas, ACS Appl. Mater. Interfaces 5(2013) 3921-3931.

[83] C. Gebald, J.A. Wurzbacher, A. Borgschulte, T. Zimmermann, A. Steinfeld, Singlecomponent and binary CO₂ and H₂O adsorption of amine-functionalized cellulose, Environ. Sci. Technol. 48(2014) 2497-2504.

[84] R. Serna-Guerrero, Y. Belmabkhout, A. Sayari, Further investigations of CO₂ capture using triamine-grafted pore-expanded mesoporous silica, Chem. Eng. J. 158(2010) 513-519.

[85] P.D. Jadhav, R.V. Chatti, R.B. Biniwale, N.K. Labhsetwar, S. Devotta, S.S. Rayalu, Monoethanol amine modified zeolite 13X for CO₂ adsorption at different temperatures, Energy Fuel 21(2007) 3555-3559.

[86] E.S. Sanz-Perez, C.R. Murdock, S.A. Didas, C.W. Jones, Direct capture of CO₂ from ambient air, Chem. Rev. 116(2016) 11840-11876.

[87] K. Li, J.D. Kress, D.S. Mebane, The mechanism of CO₂ adsorption under dry and humid conditions in mesoporous silica-supported amine sorbents, J. Phys. Chem. C 120(2016) 23683-23691.

[88] J.J. Lee, C.H. Chen, D. Shimon, S.E. Hayes, C. Sievers, C.W. Jones, Effect of humidity on the CO₂ adsorption of tertiary amine grafted SBA-15, J. Phys. Chem. C 121(2017) 23480-23487.

[89] P. Zhao, G. Zhang, Y. Sun, Y. Xu, CO₂ adsorption behavior and kinetics on aminefunctionalized composites silica with trimodal nanoporous structure, Energy Fuel 31(2017) 12508-12520.

[90] M. Fayaz, A. Sayari, Long-term effect of steam exposure on CO₂ capture performance of amine-grafted silica, ACS Appl. Mater. Interfaces 9(2017) 43747-43754.

[91] L. Wang, M. Yao, X. Hu, G. Hu, J. Lu, M. Luo, M. Fan, Amine-modified ordered mesoporous silica:The effect of pore size on CO₂ capture performance, Appl. Surf. Sci. 324(2015) 286-292.

[92] A. Heydari-Gorji, Y. Yang, A. Sayari, Effect of the pore length on CO₂ adsorption over amine-modified mesoporous silicas, Energy Fuel 25(2011) 4206-4210.

[93] C. Chen, S.T. Yang, W.S. Ahn, R. Ryoo, Amine-impregnated silica monolith with a hierarchical pore structure:Enhancement of CO₂ capture capacity, Chem. Commun. 24(2009) 3627-3629.

[94] X. Yan, L. Zhang, Y. Zhang, K. Qiao, Z. Yan, S. Komarneni, Amine-modified mesocellular silica foams for CO₂ capture, Chem. Eng. J. 168(2011) 918-924.

[95] A. Ntiamoah, J. Ling, P. Xiao, P.A. Webley, Y. Zhai, CO₂ capture by temperature swing adsorption:Use of hot CO₂-rich gas for regeneration, Ind. Eng. Chem. Res. 55(2016) 703-713.

[96] H. Krutka, S. Sjostrom, T. Starns, M. Dillon, R. Silverman, Post-combustion CO₂ capture using solid sorbents:1 MW_e pilot evaluation, Energy Procedia 37(2013) 73-88.

[97] K.M. Li, J.G. Jiang, S.C. Tian, X.J. Chen, F. Yan, Influence of silica types on synthesis and performance of amine-silica hybrid materials used for CO₂ capture, J. Phys. Chem. C 118(2014) 2454-2462.

[98] F.Y. Chang, K.J. Chao, H.H. Cheng, C.S. Tan, Adsorption of CO₂ onto amine-grafted mesoporous silicas, Sep. Purif. Technol. 70(2010) 87-95.

[99] P. Bollini, S. Choi, J.H. Drese, C.W. Jones, Oxidative degradation of aminosilica adsorbents relevant to postcombustion CO₂ capture, Energy Fuel 25(2011) 2416-2425.

[100] A. Heydari-Gorji, Y. Belmabkhout, A. Sayari, Degradation of amine-supported CO₂ adsorbents in the presence of oxygen-containing gases, Microporous Mesoporous Mater. 145(2011) 145-149.

[101] G. Calleja, R. Sanz, A. Arencibia, E.S. Sanz-Perez, Influence of drying conditions on amine-functionalized SBA-15 as adsorbent of CO₂, Top. Catal. 54(2011) 135-145.

[102] A. Sayari, Y. Belmabkhout, Stabilization of amine-containing CO₂ adsorbents:Dramatic effect of water vapor, J. Am. Chem. Soc. 132(2010) 6312-6314.

[103] A. Heydari-Gorji, A. Sayari, Thermal, oxidative, and CO₂-induced degradation of supported polyethylenimine adsorbents, Ind. Eng. Chem. Res. 51(2012) 6887-6894.

[104] T.C. Drage, A. Arenillas, K.M. Smith, C.E. Snape, Thermal stability of polyethylenimine based carbon dioxide adsorbents and its influence on selection of regeneration strategies, Microporous Mesoporous Mater. 116(2008) 504-512.

[105] A. Sayari, Y. Belmabkhout, E. Da'na, CO₂ deactivation of supported amines:Does the nature of amine matter, Langmuir 28(2012) 4241-4247.

[106] A. Sayari, A. Heydari-Gorji, Y. Yang, CO₂-induced degradation of amine-containing adsorbents:Reaction products and pathways, J. Am. Chem. Soc. 134(2012) 13834-13842.

[107] K. Kim, Y. Son, W.B. Lee, K.S. Lee, Moving bed adsorption process with internal heat integration for carbon dioxide capture, Int. J. Greenhouse Gas Control 17(2013) 13-24.

[108] T. Okumura, T. Ogino, S. Nishibe, Y. Nonaka, T. Shoji, T. Higashi, CO₂ capture test for a moving-bed system utilizing low-temperature steam, Energy Procedia 63(2014) 2249-2254.

[109] N. Hedin, L. Andersson, L. Bergstrom, J.Y. Yan, Adsorbents for the post-combustion capture of CO₂ using rapid temperature swing or vacuum swing adsorption, Appl. Energy 104(2013) 418-433.

[110] M.M.F. Hasan, R.C. Baliban, J.A. Elia, C.A. Floudas, Modeling, simulation, and optimization of postcombustion CO₂ capture for variable feed concentration and flow rate. 2. Pressure swing adsorption and vacuum swing adsorption processes, Ind. Eng. Chem. Res. 51(2012) 15665-15682.

[111] A.L. Chaffee, G.P. Knowles, Z. Liang, J. Zhang, P. Xiao, P.A. Webley, CO₂ capture by adsorption:Materials and process development, Int. J. Greenhouse Gas Control 1(2007) 11-18.

Recent progress of amine modified sorbents for capturing CO₂ from flue gas

Recent progress of amine modified sorbents for capturing CO₂ from flue gas

PDF (PC)

Knowledge

Abstract

Cite this article

share this article

References

Related Articles 15

Recommended Articles

Metrics

Comments

[1]	Haixiang Liu, Jun Zhang, Chunlei Dong, Gang Zhu, Guanben Du, Shuduan Deng. Synthesis, performance and structure characterization of glyoxal-monomethylolurea-melamine (G-MMU-M) co-condensed resin [J]. Chinese Journal of Chemical Engineering, 2023, 59(7): 92-104.
[2]	Tinghao Jia, Yunbo Yu, Qing Liu, Yao Yang, Ji-Jun Zou, Xiangwen Zhang, Lun Pan. Theoretical and experimental study on the inhibition of jet fuel oxidation by diarylamine [J]. Chinese Journal of Chemical Engineering, 2023, 56(4): 225-232.
[3]	Mengge Shang, Jing Zhang, Jinqiang Sun, Shimo Yu, Feng Hua, Xiaoxu Xuan, Xun Sun, Serguei Filatov, Xibin Yi. Amine-functionalized mesoporous UiO-66 aerogel for CO₂ adsorption [J]. Chinese Journal of Chemical Engineering, 2023, 54(2): 36-43.
[4]	Yingjun Lin. Whole-process optimization for industrial production of glucosamine sulfate sodium chloride based on QbD concept [J]. Chinese Journal of Chemical Engineering, 2023, 54(2): 153-161.
[5]	Shan Liu, Wenqi Zhong, Xi Chen, Li Sun, Lukuan Yang. Multiobjective economic model predictive control using utopia-tracking for the wet flue gas desulphurization system [J]. Chinese Journal of Chemical Engineering, 2023, 54(2): 343-352.
[6]	An Wang, Zhongyu Hou. Improving the energy efficiency of surface dielectric barrier discharge devices for plasma nitric oxide conversion utilizing active flow control [J]. Chinese Journal of Chemical Engineering, 2023, 53(1): 270-279.
[7]	Xuan Gao, Zhihui Li, Dongsheng Zhang, Xinqiang Zhao, Yanji Wang. Synthesis and kinetics of 2,5-dicyanofuran in the presence of hydroxylamine ionic liquid salts [J]. Chinese Journal of Chemical Engineering, 2023, 53(1): 310-316.
[8]	Heping Xie, Yunpeng Wang, Tao Liu, Yifan Wu, Wenchuan Jiang, Cheng Lan, Zhiyu Zhao, Liangyu Zhu, Dongsheng Yang. Electrochemical CO₂ mineralization for red mud treatment driven by hydrogen-cycled membrane electrolysis [J]. Chinese Journal of Chemical Engineering, 2022, 43(3): 14-23.
[9]	Yihan Yin, Aoqian Qiu, Hongxia Gao, Yanqing Na, Zhiwu Liang. Experimental study of the mass transfer behavior of carbon dioxide absorption into ternary phase change solution in a packed tower [J]. Chinese Journal of Chemical Engineering, 2022, 43(3): 135-142.
[10]	Xiaomeng Zhao, Xingyu Li, Changjun Liu, Shan Zhong, Houfang Lu, Hairong Yue, Kui Ma, Lei Song, Siyang Tang, Bin Liang. The quasi-activity coefficients of non-electrolytes in aqueous solution with organic ions and its application on the phase splitting behaviors prediction for CO₂ absorption [J]. Chinese Journal of Chemical Engineering, 2022, 43(3): 316-323.
[11]	Wanqiao Liang, Jihuan Huang, Penny Xiao, Ranjeet Singh, Jining Guo, Leila Dehdari, Gang Kevin Li. Amine-immobilized HY zeolite for CO₂ capture from hot flue gas [J]. Chinese Journal of Chemical Engineering, 2022, 43(3): 335-342.
[12]	Junya Wang, Kai Chen, Yi Wang, Jiuming Lei, Abdullah Alsubaie, Ping Ning, Shikun Wen, Taiping Zhang, Abdulraheem S.A. Almalki, A. Alhadhrami, Zhiping Lin, Hassan Algadi, Zhanhu Guo. Effect of K₂CO₃ doping on CO₂ sorption performance of silicate lithium-based sorbent prepared from citric acid treated sediment [J]. Chinese Journal of Chemical Engineering, 2022, 51(11): 10-20.
[13]	Sihan Li, Yuxuan Yang, Kuo Su, Bao Zhang, Yaqing Feng. Dopant-free small molecule hole transport materials based on triphenylamine derivatives for perovskite solar cells [J]. Chinese Journal of Chemical Engineering, 2022, 50(10): 29-42.
[14]	Ye Yuan, Yurui Pan, Menglong Sheng, Guangyu Xing, Ming Wang, Jixiao Wang, Zhi Wang. Synthesis and optimization of high-performance amine-based polymer for CO₂ separation [J]. Chinese Journal of Chemical Engineering, 2022, 50(10): 168-176.
[15]	Dongqi An, Yuyao Yang, Weixin Zou, Yandi Cai, Qing Tong, Jingfang Sun, Lin Dong. Insight into the promotional mechanism of Cu modification towards wide-temperature NH₃-SCR performance of NbCe catalyst [J]. Chinese Journal of Chemical Engineering, 2022, 50(10): 301-309.