Exploring aramid as emerging contender for CO2 capture

doi:10.1016/j.cjche.2016.02.003

Abstract

Abstract: To prevent CO₂ accumulation in the atmosphere generated from scorching of fossil fuels, carbon capture and sequestration (CCS) technology is considered as a potential route to mitigate the emissions of CO₂ from reaching the atmosphere. Power generation from sources such as gas, coal and biomass can fulfill the energy demand more readily than many other sources of electricity production. Thus these sources may be retained as important alternative option in the global energy cycle. In order to curtail CO₂, porous aramid network was fabricated by the condensation of 1,3,5-benzenetricarbonyl trichloride and 1,3-phenylenediamine in 1,4-dioxane solvent. Aramid was characterized for various analyses including FTIR, XRD, TGA, BET surface area and pore size analysis, FESEM and CO₂ adsorption measurements. Excellent thermal stability was provided by strong amide linkages in the polymer backbone. Optimum CO₂ uptake of aramid was achieved to be 23.14 mg·g^-1 at 273 K at 0.1 MPa. The basic amide groups of network structure showed greater affinity for CO₂. Excellent thermal stability of aramid makes it a promising sorbent for CO₂ capture in adverse conditions.

Key words: Greenhouse gas, CO₂ capture, Polymers

摘要： To prevent CO₂ accumulation in the atmosphere generated from scorching of fossil fuels, carbon capture and sequestration (CCS) technology is considered as a potential route to mitigate the emissions of CO₂ from reaching the atmosphere. Power generation from sources such as gas, coal and biomass can fulfill the energy demand more readily than many other sources of electricity production. Thus these sources may be retained as important alternative option in the global energy cycle. In order to curtail CO₂, porous aramid network was fabricated by the condensation of 1,3,5-benzenetricarbonyl trichloride and 1,3-phenylenediamine in 1,4-dioxane solvent. Aramid was characterized for various analyses including FTIR, XRD, TGA, BET surface area and pore size analysis, FESEM and CO₂ adsorption measurements. Excellent thermal stability was provided by strong amide linkages in the polymer backbone. Optimum CO₂ uptake of aramid was achieved to be 23.14 mg·g^-1 at 273 K at 0.1 MPa. The basic amide groups of network structure showed greater affinity for CO₂. Excellent thermal stability of aramid makes it a promising sorbent for CO₂ capture in adverse conditions.

关键词: Greenhouse gas, CO₂ capture, Polymers

Sonia Zulfiqar, Muhammad Ilyas Sarwar. Exploring aramid as emerging contender for CO₂ capture[J]. , 2016, 24(7): 850-855.

References

[1] S. Zulfiqar, F. Karadas, J. Park, E. Deniz, G.D. Stucky, Y. Jung, M. Atilhan, C.T. Yavuz, Amidoximes:Promising candidates for CO₂ capture, Energy Environ. Sci. 4(2011) 4528-4531.
[2] U.S. Department of Commerce, National Oceanic and Atmospheric Administration (NOAA)/Earth System Research Laboratory (ESRL), Global monitoring division, http://www.esrl.noaa.gov/gmd/ccgg/trends/, accessed October 2015
[3] K.M.K. Yu, I. Curcic, J. Gabriel, S.C.E. Tsang, Recent advances in CO₂ capture and utilization, ChemSusChem. 1(2008) 893-899.
[4] M.G. Plaza, C. Pevida, B. Arias, M.D. Casal, C.F. Martın, J. Fermoso, F. Rubiera, J.J. Pis, Different approaches for the development of low-cost CO₂ adsorbents, J. Environ. Eng. 135(2009) 426-432.
[5] D. Aaron, C. Tsouris, Separation of CO₂ from flue gas:A review, Sep. Sci. Technol. 40(2005) 321-348.
[6] F.M. Orr Jr., Carbon capture and storage:Are we ready, Energy Environ. Sci. 2(2009) 449-458.
[7] R. Steeneveldt, B. Berger, T.A. Torp, CO₂ capture and storage:Closing the knowing-doing gap, Chem. Eng. Res. Des. 84(2006) 739-763.
[8] J. Blamey, J. Anthony, J. Wang, P.S. Fennel, An overview of CO₂ capture technologies, Prog. Energy Combust. Sci. 36(2010) 260-279.
[9] D.P. Harrison, The role of solids in CO₂ capture:A mini review, Greenhouse Gas Control Technol. 7(2) (2005) 1101-1106.
[10] G.P. Knowles, J.V. Graham, S.W. Delaney, A.L. Chaffee, Aminopropyl-functionalized mesoporous silicas as CO₂ adsorbents, Fuel Process. Technol. 86(2005) 1435-1448.
[11] M.L. Gray, Y. Soong, K.J. Champagne, J. Baltrus, R.W. Stevens Jr., P. Toochinda, S.S.C. Chuang, CO₂ capture by amine-enriched fly ash carbon sorbents, Sep. Purif. Technol. 35(2004) 31-36.
[12] Y. He, X. Zhu, Y. Li, C. Peng, J. Hu, H. Liu, Efficient CO₂ capture by triptycene-based microporous organic polymer with functionalized modification, Microporous Mesoporous Mater. 214(2015) 181-187.
[13] T. Filburn, J.J. Helble, R.A. Weiss, Development of supported ethanolamines and modified ethanolamines for CO₂ capture, Ind. Eng. Chem. Res. 44(2005) 1542-1546.
[14] M. Radosz, X. Hu, K. Krutkramelis, Y. Shen, Flue-gas carbon capture on carbonaceous sorbents:Toward a low-cost multifunctional carbon filter for "green" energy producers, Ind. Eng. Chem. Res. 47(2008) 3783-3794.
[15] M.M. Maroto-Valer, Z. Tang, Y. Zhang, CO₂ capture by activated and impregnated anthracites, Fuel Process. Technol. 86(2005) 1487-1502.
[16] 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.
[17] C. Lu, H. Bai, B. Wu, F. Su, J.F. Hwang, Comparative study of CO₂ capture by carbon nanotubes, activated carbons, and zeolites, Energy Fuels 22(2008) 3050-3056.
[18] C. Pevida, M.G. Plaza, B. Arias, J. Fermoso, F. Rubiera, J.J. Pis, Surface modification of activated carbons for CO₂ capture, Appl. Surf. Sci. 254(2008) 7165-7172.
[19] S. Zulfiqar, M.I. Sarwar, Probing the potential of polyester for CO₂ capture, J. Environ. Sci. 26(2014) 1423-1427.
[20] C. Pevida, T.C. Drage, C.E. Snape, Silica-templated melamine-formaldehyde resin derived adsorbents for CO₂ capture, Carbon 46(2008) 1464-1474.
[21] T.C. Drage, J.M. Blackman, C. Pevida, C.E. Snape, Evaluation of activated carbon adsorbents for CO₂ capture in gasification, Energy Fuel 23(2009) 2790-2796.
[22] H. Hayashi, J. Taniuchi, N. Furuyashiki, S. Sugiyama, Efficient recovery of carbon dioxide from flue gases of coal-fired power plants by cyclic fixed-bed operations over K₂CO₃-on-carbon, Ind. Eng. Chem. Res. 37(1998) 185-191.
[23] N. Shigemoto, T. Yanagihara, S. Sugiyama, H. Hayashi, Material balance and energy consumption for CO₂ recovery from moist flue gas employing K₂CO₃-on-activated carbon and its evaluation for practical adaptation, Energy Fuel 20(2006) 721-726.
[24] S. Zulfiqar, M.I. Sarwar, D. Mecerreyes, Polymeric ionic liquids for CO₂ capture and separation:Potential, progress and challenges, Polym. Chem. 6(2015) 6435-6451.
[25] J. Merel, M. Clausse, F.Meunier, Experimental investigation on CO₂ post-combustion capture by indirect thermal swing adsorption using 13X and 5 A zeolites, Ind. Eng. Chem. Res. 47(2008) 209-215.
[26] D. Ko, R. Siriwardane, L.T. Biegler, Optimization of a pressure-swing adsorption process using zeolite 13X for CO₂ sequestration, Ind. Eng. Chem. Res. 42(2003) 339-348.
[27] S. Cavenati, C.A. Grande, A.E. Rodrigues, Adsorption equilibrium of methane, carbon dioxide, and nitrogen on zeolite 13X at high pressures, J. Chem. Eng. Data 49(2004) 1095-1101.
[28] A.P. Cote, A.I. Benin, N.W. Ockwig,M. O'Keeffe, A.J.Matzger, O.M. Yaghi, Porous, crystalline, covalent organic frameworks, Science 310(2005) 1166-1170.
[29] H.M. El-Kaderi, J.R. Hunt, J.L. Mendoza-Cortes, A.P. Cote, R.E. Taylor, M. O'Keeff, O.M. Yaghi, Designed synthesis of 3D covalent organic frameworks, Science 316(2007) 268-272.
[30] F.J. Uribe-Romo, J.R. Hunt, H. Furukawa, C. Kloeck, M. O'Keeffe, O.M. Yaghi, A crystalline imine-linked 3-D porous covalent organic framework, J. Am. Chem. Soc. 131(2009) 4570-4571.
[31] P. Kuhn, M. Antonietti, A. Thomas, Porous, covalent triazine-based frameworks prepared by ionothermal synthesis, Angew. Chem. Int. Ed. 47(2008) 3450-3453.
[32] P. Kuhn, A. Forget, D. Su, A. Thomas, M. Antonietti, From microporous regular frameworks to mesoporous materials with ultrahigh surface area:Dynamic reorganization of porous polymer networks, J. Am. Chem. Soc. 130(2008) 13333-13337.
[33] R. Chinchilla, C. Najera, The Sonogashira reaction:A booming methodology in synthetic organic chemistry, Chem. Rev. 107(2007) 874-922.
[34] J.-X. Jiang, F. Su, A. Trewin, C.D. Wood, N.L. Campbell, H. Niu, C. Dickinson, A.Y. Ganin, M.J. Rosseinsky, Y.Z. Khimyak, A.I. Cooper, Conjugated microporous poly(aryleneethynylene) networks, Angew. Chem. Int. Ed. 46(2007) 8574-8578.
[35] J.-X. Jiang, F. Su, A. Trewin, C.D.Wood, H. Niu, J.T.A. Jones, Y.Z. Khimyak, A.I. Cooper, Synthetic control of the pore dimension and surface area in conjugatedmicroporous polymer and copolymer networks, J. Am. Chem. Soc. 130(2008) 7710-7720.
[36] J.-X. Jiang, A. Trewin, F. Su, C.D.Wood, H. Niu, J.T.A. Jones, Y.Z. Khimyak, A.I. Cooper, Microporous poly(tri(4-ethynylphenyl)amine) networks:Synthesis, properties, and atomistic simulation, Macromolecules 42(2009) 2658-2666.
[37] T. Ben, H. Ren, S. Ma, D. Cao, J. Lan, X. Jing,W.Wang, J. Xu, F. Deng, J.M. Simmons, S. Qiu, G. Zhu, Targeted synthesis of a porous aromatic framework with high stability and exceptionally high surface area, Angew. Chem. Int. Ed. 48(2009) 9457-9460.
[38] N.B. McKeown, P.M. Budd, Exploitation of intrinsic microporosity in polymer-based materials, Macromolecules 43(2010) 5163-5176.
[39] Y. Luo, B. Li,W.Wang, K.Wu, B. Tan, Hypercrosslinked aromatic heterocyclic microporous polymers:A new class of highly selective CO₂ capturing materials, Adv. Mater. 24(2012) 5703-5707.
[40] J.Y. Lee, C.D. Wood, D. Bradshaw, M.J. Rosseinsky, A.I. Cooper, Hydrogen adsorption in microporous hypercrosslinked polymers, Chem. Commun. 2670-2672(2006).
[41] M. Karahan, A. Kus, R. Eren, An investigation into ballistic performance and energy absorption capabilities of woven aramid fabrics, Int. J. Impact Eng. 35(2008) 499-510.
[42] M. Karahan, Comparison of ballistic performance and energy absorption capabilities of woven and unidirectional aramid fabrics, Text. Res. J. 78(2008) 718-730.
[43] Q. Chen, J.-X. Wang, F. Yang, D. Zhou, N. Bian, X.-J. Zhang, C.-G. Yan, B.-H. Han, Tetraphenylethylene-based fluorescent porous organic polymers:Preparation, gas sorption properties and photoluminescence properties, J. Mater. Chem. 21(2011) 13554-13560.
[44] R.V. Siriwardane, M.S. Shen, E.P. Fisher, J.A. Poston, Adsorption of CO₂ on molecular sieves and activated carbon, Energy Fuel 15(2001) 279-284.
[45] D.M. Ruthven, Principles of adsorption and adsorption processes, Wiley, NY, 1984.
[46] R. Dawson, D.J. Adams, A.I. Cooper, Chemical tuning of CO₂ sorption in robust nanoporous organic polymers, Chem. Sci. 2(2011) 1173-1177.
[47] Y.-C. Zhao, T.Wang, L.-M. Zhang, Y. Cui, B.-H. Han, Facile approach to preparing microporous organic polymers through benzoin condensation, ACS Appl. Mater. Interfaces 4(2012) 6975-6981.
[48] S. Zulfiqar, S. Awan, F. Karadas, M. Atilhan, C.T. Yavuz, M.I. Sarwar, Amidoxime porous polymers for CO₂ capture, RSC Adv. 3(2013) 17203-17213.
[49] S. Zulfiqar, M.I. Sarwar, C.T. Yavuz, Melamine based porous organic amide polymers for CO₂ capture, RSC Adv. 4(2014) 52263-52269.
[50] S. Zulfiqar, M.I. Sarwar, Effect of solvent on the CO₂ capture ability of polyester:A comparative study, J. Ind. Eng. Chem. 21(2015) 1373-1378.

Exploring aramid as emerging contender for CO₂ capture

Exploring aramid as emerging contender for CO₂ capture

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