Carbon capture by physical adsorption: Materials, experimental investigations and numerical modeling and simulations - A review

Applied Energy

Volumn 161, Issue , 2016, Pages 225-255

  Ben Mansour, R ^a   Habib, M A ^a   Bamidele, O E ^a   Basha, M ^a   Qasem, N A A ^a   Peedikakkal, A ^a   Laoui, T ^a   Ali, M ^a  

^a KING ABDULAZIZ CITY FOR SCIENCE AND TECHNOLOGY   (Saudi Arabia)

Author keywords

Adsorption techniques; Carbon capture; Experimental studies; Numerical investigations; Post combustion

Indexed keywords

ADSORPTION; CARBON CAPTURE; CARBON DIOXIDE PROCESS; COMBUSTION; EXHAUST GASES; NUMERICAL MODELS; SEPARATION; SMALL POWER PLANTS;

ADSORPTION MATERIALS; EXPERIMENTAL INVESTIGATIONS; EXPERIMENTAL STUDIES; HIGH ADSORPTION CAPACITY; MODEL AND SIMULATION; NUMERICAL INVESTIGATIONS; POST-COMBUSTION; POST-COMBUSTION CARBON CAPTURES;

CARBON DIOXIDE;

ADSORPTION; CARBON DIOXIDE; COMBUSTION; EXHAUST EMISSION; EXPERIMENTAL STUDY; NUMERICAL MODEL; POWER PLANT; SEPARATION; WATER VAPOR;

EID: 84944463571     PISSN: 03062619     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.apenergy.2015.10.011     Document Type: Review

References (198)

1. IPCC. Special report on carbon dioxide capture and storage. In: Metz B, Davidson O, Coninct H, Loos M, Meyer L, editor. Cambridge (University Press); 2005. http://ipcc.ch/report/srccs/.
2. D'Alessandro D.M., McDonald T. Toward carbon dioxide capture using nanoporous materials. Pure Appl Chem 2011, 83(1):57-66.
3. GCEP Energy Assessment Analysis Project. Global climate & energy project an assessment of carbon capture technology and research opportunities. In: 2005, Global Climate & Energy Project, Stanford University.
4. Herzog H., Meldon J., Hatton A. Advanced post-combustion CO2 capture 2009, Clean Air Task Force, April.
5. Li B., et al. Enhanced binding affinity, remarkable selectivity, and high capacity of CO2 by dual functionalization of a rht-type metal-organic framework. Angew Chem Int Ed 2012, 51:1412-1415.
6. Li H., Ditaranto M., Yan J. Carbon capture with low energy penalty: supplementary fired natural gas combined cycles. Appl Energy 2012, 97:164-169. 10.1016/j.apenergy.2011.12.034.
7. Li J.R., Sculley J., Zhou H.C. Metal-organic frameworks for separations. Chem Rev 2012, 112(2):869-932.
8. Li G., Xiao P., Xu D., Webley P.A. Dual mode roll-up effect in multicomponent non-isothermal adsorption processes with multilayered bed packing. Chem Eng Sci 2011, 66(9):1825-1834.
9. Li J.R., Ma Y., McCarthy M.C., Sculley J., Yu J., Jeong H.K., et al. Carbon dioxide capture-related gas adsorption and separation in metal-organic frameworks. Coord Chem Rev 2011, 255(15-16):1791-1823.
10. Dong R., Lu H., Yu Y., Zhang Z. A feasible process for simultaneous removal of CO2, SO2 and NOx in the cement industry by NH3 scrubbing. Appl Energy 2012, 97(x):185-191. 10.1016/j.apenergy.2011.12.039.
11. Lv Y., Yu X., Jia J., Tu S.-T., Yan J., Dahlquist E. Fabrication and characterization of superhydrophobic polypropylene hollow fiber membranes for carbon dioxide absorption. Appl Energy 2012, 90(1):167-174. 10.1016/j.apenergy.2010.12.038.
12. Lv Y., Yu X., Tu S.-T., Yan J., Dahlquist E. Experimental studies on simultaneous removal of CO2 and SO2 in a polypropylene hollow fiber membrane contactor. Appl Energy 2012, 97:283-288. 10.1016/j.apenergy.2012.01.034.
13. Song C.F., Kitamura Y., Li S.H. Evaluation of stirling cooler system for cryogenic CO2 capture. Appl Energy 2012, 98:491-501. 10.1016/j.apenergy.2012.04.013.
14. Van Benthum R.J., van Kemenade H.P., Brouwers J.J.H., Golombok M. Condensed rotational separation of CO2. Appl Energy 2012, 93:457-465. 10.1016/j.apenergy.2011.12.025.
15. Zhang M., Guo Y. Rate based modeling of absorption and regeneration for CO2 capture by aqueous ammonia solution. Appl Energy 2013, 111(x):142-152. 10.1016/j.apenergy.2013.04.074.
16. Yan S., Fang M., Wang Z., Luo Z. Regeneration performance of CO2-rich solvents by using membrane vacuum regeneration technology: Relationships between absorbent structure and regeneration efficiency. Appl Energy 2012, 98:357-367. 10.1016/j.apenergy.2012.03.055.
17. Nakamura T. Recovery and sequestration of CO2 from stationary combustion systems by photosynthesis of microalgae quarterly technical progress report # 9 reporting period start date: 1 October 2002 Reporting Period End Date : 31 December 2002 Prepared by National Energy; 2003.
18. Songolzadeh M., Ravanchi M.T., Soleimani M. Carbon dioxide capture and storage: a general review on adsorbents. World Acad Sci Eng Technol 2012, 225-232.
19. 2 capture from flue gases using pressure swing adsorption. Ind Eng Chem Res 2008, 47(14):4883-4890.
20. Yoo J., Cho S.H., Yang T. Comparison of activated carbon and zeolite 13X for COa recovery from flue gas by pressure swing adsorption. Ind Eng Chem Res 1995, 34:591-598.
21. 4/CO gas mixtures at high pressures. Microporous Mesoporous Mater 2012, 156(July):217-223.
22. Krishna R., van Baten J.M. A comparison of the CO2 capture characteristics of zeolites and metal-organic frameworks. Sep Purif Technol 2012, 87:120-126.
23. Clausse M., Bonjour J., Meunier F. Adsorption of gas mixtures in TSA adsorbers under various heat removal conditions. Chem Eng Sci 2004, 59(17):3657-3670.
24. Mason J., Sumida K., Herm Z.R., Krishna R., Long J.R. Evaluating metal-organic frameworks for post-combustion carbon dioxide capture via temperature swing adsorption. Energy Environ Sci 2011, 4(8):3030.
25. Li J.R., Kuppler R.J., Zhou H.C. Selective gas adsorption and separation in metal-organic frameworks. Chem Soc Rev 2009, 38:1477.
26. Choi S., Drese J.H., Jones C.W. Adsorbent materials for carbon dioxide capture from large anthropogenic point sources. Chem Sus Chem 2009, 2:796.
27. Zhao D., Yuan D., Yakovenko A., Zhou H.-C. A NbO-type metal-organic framework derived from a polyyne-coupled di-isophthalate linker formed in situ. Chem Commun (Camb) 2010, 46(23):4196-4198.
28. Zhao D., Yuan D., Krishna R., van Baten J.M., Zhou H.-C. Thermosensitive gating effect and selective gas adsorption in a porous coordination nanocage. Chem Commun (Camb) 2010, 46(39):7352-7354.
29. Akhtar F., Andersson L., Keshavarzi N., Bergström L. Colloidal processing and CO2 capture performance of sacrificially templated zeolite monoliths. Appl Energy 2012, 97:289-296. 10.1016/j.apenergy.2011.12.064.
30. Wang J., Manovic V., Wu Y., Anthony E.J. A study on the activity of CaO-based sorbents for capturing CO2 in clean energy processes. Appl Energy 2010, 87(4):1453-1458. 10.1016/j.apenergy.2009.08.010.
31. Sun R., Li Y., Liu H., Wu S., Lu C. CO2 capture performance of calcium-based sorbent doped with manganese salts during calcium looping cycle. Appl Energy 2012, 89(1):368-373. 10.1016/j.apenergy.2011.07.051.
32. 2 adsorbing materials for zero emission power generation systems. Energy Fuels 2007, 21:426.
33. Yamaguchi T., Niitsuma T., Nair B.N., Nakagawa K. Lithium silicate based membranes for high temperature CO2 separation. J Membr Sci 2007, 294:16.
34. 3 as sorbent: sorption kinetics and reactor simulation. Catal Today 2005, 106:41.
35. Ma S., Simmons J.M., Yuan D., Li J.-R., Weng W., Liu D.-J., et al. A nanotubular metal-organic framework with permanent porosity: structure analysis and gas sorption studies. Chem Commun (Camb) 2009, 1(27):4049-4051.
36. Webb P.A. Introduction to chemical adsorption analytical techniques and their applications to catalysis 2003, MIC Technical Publications.
37. Yu C., Hung C., Tan C. A review of CO2 capture by absorption and adsorption. Aerosol Air Qual Res 2012, 745-769.
38. 2 on molecular sieves and activated carbon. Energy Fuels 2001, 15:279-284.
39. Harlick P.J.E., Sayari A. Applications of pore-expanded mesoporous silicas, triamine silane grafting for enhanced CO2 adsorption". Ind Eng Chem Res 2006, 45:3248.
40. Chue K.T., Kim J.N., Yoo Y.U., Cho S.H., Yang R.T. Comparison of activated carbon and zeolite 13X for CO2 recovery from flue gas by pressure swing adsorption. Ind Eng Chem Res 1995, 34:591.
41. Maurin G., Llewellyn P.L., Bell R.G. Adsorption mechanism of carbon dioxide in faujasites: grand canonical monte carlo simulations and microcalorimetry measurements. J Phys Chem B 2005, 109:16084.
42. 2 reversibly. J Am Chem Soc 2008, 130:2902.
43. Leal O., Bolivar C., Ovalles C., Garcia J., Espidel Y. Reversible adsorption of carbon dioxide on amine surface-bonded silica gel. Inorg Chim Acta 1995, 240:183.
44. Sirwardane RV. Solid sorbents for removal of carbon dioxide from gas streams at low temperatures. U.S. Patent 6,908,497 B1, 1, 2005.
45. Xu X., Song C., Miller B.G., Scaroni A.W. Adsorption separation of carbon dioxide from flue gas of natural gas-fired boiler by a novel nanoporous. Fuel Process Technol 2005, 86:1457.
46. 2 capture. Ind Eng Chem Res 2008, 47:7419.
47. Hiyoshi N., Yogo D.K., Yashima T. Adsorption of carbon dioxide on amine modified SBA-15 in the presence of water vapor. Chem Lett 2004, 33:510.
48. Mazumder S., van Hemert P., Busch A., Wolf K.-H., Tejera-Cuesta P. Flue gas and pure CO2 sorption properties of coal: a comparative study. Int J Coal Geol 2006, 67:267.
49. Plaza M.G., González A.S., Pevida C., Pis J.J., Rubiera F. Valorisation of spent coffee grounds as CO2 adsorbents for postcombustion capture applications. Appl Energy 2012, 99:272-279. 10.1016/j.apenergy.2012.05.028.
50. 2 capture capacity of carbons. Sep Purif Technol 2010, 74:225.
51. 2 adsorption capacity on carbon molecular sieves at room temperature. Chem Commun 2011, 47:6840.
52. Plaza M.G., Pevida C., Arias B., Fermoso J., Arenillas A., Rubiera F., et al. Therm Anal Calorimeters 2008, 92:601-606.
53. Radosz M., Hu X., Krutkramelis K., Shen Y. Flue-gas carbon capture on carbonaceous sorbents: toward a low-cost multifunctional carbon filter for "green" energy producers. Ind Eng Chem Res 2008, 47:3783.
54. Thallapally P.K., McGrail P.B., Atwood J.L., Gaeta C., Tedesco C., Neri P. Carbon dioxide capture in a self-assembled organic nanochannels. Chem Mater 2007, 19:3355.
55. Thallapally P.K., McGrail P.B., Dalgarno S.J., Schaef H.T., Tian J., Atwood J.L. Gas-induced transformation and expansion of a non-porous organic solid. Nat Mater 2008, 7:146.
56. Furukawa H., Yaghi O.M. Storage of hydrogen, methane, and carbon dioxide in highly porous covalent organic frameworks for clean energy applications. J Am Chem Soc 2009, 131:8876.
57. 2 storage. Langmuir 2008, 24:6270.
58. Babarao R., Jiang J.W. Unprecedentedly high selective adsorption of gas mixtures in rho zeolite-like metal-organic framework: a molecular simulation study. J Am Chem Soc 2009, 131:11417.
59. Deng S., Wei H., Chen T., Wang B., Huang J., Yu G. Superior CO2 adsorption on pine nut shell-derived activated carbons and the effective micropores at different temperatures. Chem Eng J 2014, 253:46-54. 1 October.
60. Heidari A., Younesi H., Rashidi A., Ghoreyshi A.A. Evaluation of CO2 adsorption with eucalyptus wood based activated carbon modified by ammonia solution through heat treatment. Chem Eng J 2014, 254:503-513. 15 October.
61. Balsamo M., Budinova T., Erto A., Lancia A., Petrova B., Petrov N., et al. CO2 adsorption onto synthetic activated carbon: kinetic, thermodynamic and regeneration studies. Sep Purif Technol 2013, 116:214-221. 15 September.
62. Yin G., Liu Z., Liu Q., Wu W. The role of different properties of activated carbon in CO2 adsorption. Chem Eng J 2013, 230(15):133-140.
63. Caglayan B.S., Erhan Aksoylu A. CO2 adsorption on chemically modified activated carbon. J Hazard Mater 2013, 252-253:19-28. 15 May.
64. Babu D.J., Lange M., Cherkashinin G., Issanin A., Staudt R., Schneider J.J. Gas adsorption studies of CO2 and N2 in spatially aligned double-walled carbon nanotube arrays. Carbon 2013, 61(September):616-623.
65. 2. J Hazard Mater 2012, 227-228:317-326. 15 August.
66. Hsu S.C., Lu C., Su F., Zeng W., Chen W. Thermodynamics and regeneration studies of CO2 adsorption on multi-walled carbon nanotubes. Chem Eng Sci 2010, 65(4):1354-1361.
67. Lithoxoos G.P., Labropoulos A., Peristeras L.D., Kanellopoulos N., Samios J., Economou I.G. Adsorption of N2, CH4, CO and CO2 gases in single walled carbon nanotubes: a combined experimental and Monte Carlo molecular simulation study. J Supercrit Fluids 2010, 55(2):510-523.
68. Su F., Lu C., Cnen W., Bai H., Hwang J.F. Capture of CO2 from flue gas via multiwalled carbon nanotubes. Sci Total Environ 2009, 407(8):3017-3023.
69. 2 adsorption in single-walled carbon nanotubes. Chem Phys Lett 2003, 376(5-6):761-766.
70. 2 from flue gas on activated carbon fibre. Chem Eng J 2012, 200-202(15):399-404.
71. Yang H., Gong M., Chen Y. Preparation of activated carbons and their adsorption properties for greenhouse gases: CH4 and CO2. J Nat Gas Chem 2011, 20(5):460-464.
72. Zhang Z., Xu M., Wang H., Li Z. Enhancement of CO2 adsorption on high surface area activated carbon modified by N2, H2 and ammonia. Chem Eng J 2010, 160(2):571-577.
73. 2 on activated carbon beads. Chem Eng J 2010, 160(2):398-407.
74. 4 gas separation on activated carbon fibers-electric swing adsorption. J Colloid Interface Sci 2006, 298(2):523-528.
75. Iijima S. Helical microtubules of graphitic carbon. Nature 1991, 354:56.
76. Abuilaiwi F.A., Laoui T., Al-HArthi M., Mautaz A.A. Modification and functionalization of multiwalled carbon nanotube (MWCNT) via Fischer esterification. Arabian J Sci Eng 2010, 35(1C):37.
77. Ebbesen T.W., Ajayan P.M. Large-scale synthesis of carbon nanotubes. Nature 1992, 358(6383):220-222.
78. Thess A., Lee R.P., Nikolaev H.J., Dai P., Petit J., Robert C.H., et al. Crystalline ropes of metallic carbon nanotubes. Science 1996, 273(52):483-487.
79. Deepak S., Chenyu W., Kyeongjae C. Nanomechanics of carbon nanotubes and composites. ASME 2003, 56(2):215-229.
80. Harris P. Carbon nanotubes and related structures: new materials for the twenty first century 2001, Cambridge University Press, United Kingdom.
81. Ching-Hwa K., William G., Robert B., Donald S. Carbon nanotubes with single-layer walls. Carbon 1995, 33(7):903-914.
82. Jung S.H., Kim M.R., Jeong S.H., Kim S.U., Lee O.J., Lee K.H., et al. High-yield synthesis of multi-walled carbon nanotubes by arc discharge in liquid nitrogen. Appl Phys A - Mater Sci Process 2003, 76(2):285-286.
83. Journet C., Bernier P. Production of carbon nanotubes. Appl Phys A - Mater Sci Process 1998, 67(1):1-9.
84. Andreas T., Roland L., Pavel N., Hongjie D., Pierre P., Jerome R., et al. Crystalline ropes of metallic carbon nanotubes. Science 1996, 273:483-487.
85. Kabbashi N.A., Muataz A.A., Al-Mamun A., Mohamed E.S., Alam M.Z., Yahya N. Kinetic adsorption of application of carbon nanotubes for Pb(II) removal from aqueous solution. J Environ Sci 2009, 21:539-544.
86. Tawabini, Al-Khaldi S., Muataz A.A., Khaled M. Removal of mercury from water by multi-walled carbon nanotubes. Water Sci Technol 2010, 61(3):591.
87. Muataz A.A., Bakather O.Y., Tawabini B.S., Bukhari A.A., Khaled M., Al-Harthi M., et al. Removal of chromium (III) from water by using modified and nonmodified carbon nanotubes. J Nanomater 2010, 9 pages.
88. Muataz A.A., Omer Y.B., Alaadin A.B., Faraj A.A., Mohamed F. Effect of carboxylic functional group functionalize on carbon nanotubes surface on the removal of lead from water. J Bioinorgan Chem Appl 2010, 9.
89. Tawabini S., AL-Khaldi S.F., Khaled M.M., Muataz A.A. Removal of arsenic from water by iron oxide nanoparticles impregnated on carbon nanotubes. J Environ Sci Health Part A 2011, 46:215-223.
90. Al-Hakami S.M., Khalil A.B., Laoui T., Atieh M.A. Fast disinfection of escherichia coli bacteria using carbon nanotubes interaction with microwave radiation. Bioinorg Chem Appl 2013, 458943:1-9.
91. Zeino A., Abulkibash A., Khaled M., Atieh M. Bromate removal from water using doped iron nanoparticles on multi-walled carbon nanotubes (CNTs). J Nanomater 2014, 2014:1-9.
92. Fatemi S., Vesali-Naseh M., Cyrus M., Hashemi J. Improving CO2/CH4 adsorptive selectivity of carbon nanotubes by functionalization with nitrogen-containing groups. Chem Eng Res Des 2011, 89(9):1669-1675.
93. Gui M.M., Yap Y.X., Chai S.P., Mohamed A. Multi-walled carbon nanotubes modified with (3-aminopropyl)triethoxysilane for effective carbon dioxide adsorption. Int J Greenhouse Gas Control 2013, 14(May):65-73.
94. 2 capture with amine-loaded carbon nanotubes via a dual-column temperature/vacuum swing adsorption. Appl Energy 2014, 113(January):706-712.
95. Liu Q., Shi Y., Zheng S., Ning L., Ye Q., Tao M., et al. Amine-functionalized low-cost industrial grade multi-walled carbon nanotubes for the capture of carbon dioxide. J Energy Chem 2014, 23(1):111-118.
96. Su F., Lu C., Chen H.-S. Adsorption, desorption, and thermodynamic studies of CO(2) with high-amine-loaded multiwalled carbon nanotubes. Langmuir 2011, 27(13):8090-8098.
97. Dillon E.P., Crouse C.A., Barron A.R. Synthesis, characterization, and carbon dioxide adsorption of covalently attached polyethyleneimine-functionalized single-wall carbon nanotubes. ACS Nano 2008, 2(1):156-164.
98. Zhao Y.Y., T Jung B., Ansaloni L., Ho W.S.W. Multiwalled carbon nanotube mixed matrix membranes containing amines for high pressure CO2/H2 separation. J Membr Sci 2014, 459:233-243.
99. Düren T. How does the pore morphology influence the adsorption performance of metal-organic frameworks: a molecular simulation study of methane and ethane adsorption in Zn-MOFs. In: International zeolite conference, vol. i; 2007.p. 2042-2047.
100. Furukawa H., Cordova K.E., O'Keeffe M., Yaghi O.M. The chemistry and applications of metal-organic frameworks. Science 2013, 341:1230444.
101. Kuppler R.J., Timmons D.J., Fang Q.-R., Li J.-R., Makal T.a., Young M.D., et al. Potential applications of metal-organic frameworks. Coord Chem Rev 2009, 253(23-24):3042-3066.
102. Lu H. Interfacial synthesis of metal-organic frameworks 2012, McMaster University.
103. Carné-Sánchez A., Imaz I., Cano-Sarabia M., Maspoch D. A spray-drying strategy for synthesis of nanoscale metal-organic frameworks and their assembly into hollow superstructures. Nat Chem 2013, 5(3):203-211.
104. Campagnol N., Van Assche T., Boudewijns T., Denayer J., Binnemans K., De Vos D., et al. High pressure, high temperature electrochemical synthesis of metal-organic frameworks: films of MIL-100 (Fe) and HKUST-1 in different morphologies. J Mater Chem A 2013, 1(19):5827.
105. Li M., Dinc M. Reductive electrosynthesis of crystalline metal-organic frameworks 2014, American Chemical Society (MIT Open Access Articles).
106. Monika P. High throughput assisted investigation on lanthanide (III) tetrakisphosphonates 2009, Ludwig-Maximilans-Universitat Munchen.
107. 2 capture ability at moderate temperatures across multiple capture and release cycles. Chem Eng J 2010, 156(2):465-470.
108. Kharissova OV, Kharisov BI, Méndez UO. Microwave-assisted synthesis of coordination and organometallic compounds. INTECH; 2009.
109. CCDC. Support Solution @ ; 2014. http://www.ccdc.cam.ac.uk.
110. Plaines D, Levan D, Brandani S, Snurr R, Matzger A, Arbor A. Carbon dioxide removal from flue gas using microporous metal organic frameworks final technical report reporting start date : reporting end date : principal author : report issued : DOE Award Number : Submitting Organization : 1 April 2007 Richard Willis; 2010.
111. Zhao Z., Li Z., Lin Y.S. Adsorption and diffusion of carbon dioxide on metal-organic framework (MOF-5). Ind Eng Chem Res 2009, 48:10015-10020.
112. Xie L.H., Suh M.P. Flexible metal-organic framework with hydrophobic pores. Chemistry 2011, 17(49):13653-13656.
113. Yuan D., Zhao D., Zhou H.-C. Pressure-responsive curvature change of a 'rigid' geodesic ligand in a (3,24)-connected mesoporous metal-organic framework. Inorg Chem 2011, 50(21):10528-10530.
114. Coudert F.X. The osmotic framework adsorbed solution theory: predicting mixture coadsorption in flexible nanoporous materials. Phys Chem Chem Phys 2010, 12(36):10904-10913.
115. Yuan D., Getman R.B., Wei Z., Snurr R.Q., Zhou H.-C. Stepwise adsorption in a mesoporous metal-organic framework: experimental and computational analysis. Chem Commun (Camb) 2012, 48(27):3297-3299.
116. Zhao G., Aziz B., Hedin N. Carbon dioxide adsorption on mesoporous silica surfaces containing amine-like motifs. Appl Energy 2010, 87(9):2907-2913. 10.1016/j.apenergy.2009.06.008.
117. Mellot-draznieks C., Fuchs A.H., Boutin A. Prediction of breathing and gate-opening transitions upon binary mixture adsorption in metal-organic frameworks franc. JACS Commun 2009, 11329-11331.
118. Nakhla J. Metal-organic-frameworks @ . Aldrich Chem files; 2009. http://www.sigmaaldrich.com.
119. Leus K. The development of vanadium and titanium containing metal organic frameworks for applications in adsorption and heterogeneous catalysis karen leus department of inorganic and physical chemistry. Universiteit Ganet; 2012.
120. González A., Plaza M., Pis J., Rubiera F., Pevida C. Post-combustion CO2 capture adsorbents from spent coffee. Energy Procedia 2013, 37:134-141.
121. Marco-Lozar J.P., Kunowsky M., Suarez-Garcia F., Linares-Solano A. Sorbent design for CO2 capture under different flue gas conditions. Carbon 2014, 72:125-134.
122. 2 capture with a commercial activated carbon: comparison of different regeneration strategies. Chem Eng J 2010, 163:41-47.
123. Thiruvenkatachari R., Su S., Yu X.X., Bae J.-S. Application of carbon fibre composites to CO2 capture from flue gas. Int J Greenhouse Gas Control 2013, 13:191-200.
124. González A., Plaza M., Rubiera F., Pevida C. Sustainable biomass-based carbon adsorbents for post-combustion capture. Chem Eng J 2013, 230:456-465.
125. Gil M.V., Alvarez-Gutierrez N., Martinez M., Rubiera F., Pevida C., Moran A. Carbon adsorbents for CO2 capture from bio-hydrogen and biogas streams: breakthrough adsorption study. Chem Eng J 2015, 269:148-158.
126. Hosseini Soraya, Bayesti Iman, Marahel Ehsan, Babadi Farahnaz Eghbali, Abdullah Luqman Chuah, Choong Thomas S.Y. Adsorption of carbon dioxide using activated carbon impregnated with Cu promoted by zinc. J Taiwan Instit Chem Eng 2015, 52:109-117.
127. Dantas T.L.P., Luna F.M.T., Silva I.J., Torres A.E.B., De Azevedo D.C.S., Rodrigues A.E., et al. Modeling of the fixed-bed adsorption of carbon dioxide and a carbon dioxide-nitrogen mixture on zeolite 13X. Brazilian J Chem Eng 2011, 28(03):533-544.
128. Dantas T.L.P., Luna F.M.T., Silva I.J., de Azevedo D.C.S., Grande C.A., Rodrigues A.E., et al. Carbon dioxide-nitrogen separation through adsorption on activated carbon in a fixed bed. Chem Eng J 2011, 169(1-3):11-19.
129. Dantas T.L., Luna F.M.T., Silva I.J., Torres A.E.B., Azevedo DCd, Rodriguesc A.E., et al. Carbon dioxide-nitrogen separation through pressure swing adsorption. Chem Eng J 2011, 172:698-704.
130. Wang L., Liu Z., Li P., Yu J., Rodrigues A.E. Experimental and modeling investigation on post-combustion carbon dioxide capture using zeolite 13X-APG by hybrid VTSA process. Chem Eng J 2012, 197:151-161.
131. Cho Youngmin, et al. LiOH-embedded zeolite for carbon dioxide capture under ambient conditions. J Ind Eng Chem 2015, 22:350-356.
132. Hefti Max, Marx Dorian, Joss Lisa, Mazzotti Marco Adsorption equilibrium of binary mixtures of carbon dioxide and nitrogen on zeolites ZSM-5 and 13X. Microporous Mesoporous Mater 2015, 215:215-228.
133. Ye Sheng, et al. Post-combustion CO2 capture with the HKUST-1 and MIL-101(Cr) metal-organic frameworks: Adsorption, separation and regeneration investigations. Microporous Mesoporous Mater 2013, 179:191-197.
134. Xu W.W., Pramanik S., Zhang Z., Emge T.J., Li J. Microporous metalorganicframework[M2(hfipbb)2(ted)] (M1/4Zn, Co; H2hfipbb1/44,4-(hexafluoroisopropylidene)-bis(benzoicacid); ted1/4triethylenediamine):Synthesis, structure analysis, pore characterization, smallgasadsorptionandCO2/N2 separation properties. J Solid State Chem 2013, 200:1-6.
135. Sabouni R., Kazemian H., Rohani S. Carbon dioxide adsorption in microwave-synthesized metal organic framework CPM-5: equilibrium and kinetics study. Microporous Mesoporous Mater 2013, 175:85-91.
136. Millward A.R., Yaghi O.M. Metal-organic frameworks with exceptionally high capacity for storage of carbon dioxide at room temperature. J Am Chem Soc 2005, 127:17998-17999.
137. Nalaparaju A., Khurana M., Farooq S., Karimi I.A., Jiang J.W. CO2 capture in cation-exchanged metal-organic frameworks: holistic modeling from molecular simulation to process optimization. Chem Eng Sci 2015, 124:70-78.
138. Camacho Barbara C.R., Ribeiro Rui P.P.L., Esteves Isabel A.A.C., Mota Jose P.B. Adsorption equilibrium of carbon dioxide and nitrogen on the MIL-53 (Al) metal organic framework. Sep Purif Technol 2015, 141:150-159.
139. Xian Shikai, Peng Junjie, Zhang Zhijuan, Xia Qibin, Wang Haihui, Li Zhong Highly enhanced and weakened adsorption properties of two MOFs by water vapor for separation of CO2/CH4 and CO2/N2 binary mixtures. Chem Eng J 2015, 270:385-392.
140. Hedin N., Andersson L., Bergström L., Yan J. Adsorbents for the post-combustion capture of CO2 using rapid temperature swing or vacuum swing adsorption. Appl Energy 2013, 104:418-433. 10.1016/j.apenergy.2012.11.034.
141. Sumida K., Rogow D.L., Mason J.A., McDonald T.M., Bloch E.D., Herm Z.R., et al. Carbon dioxide capture in metal-organic frameworks. Chem Rev 2012.
142. Andersen A., Divekar S., Dasgupta S., Cavka J.H., Nanoti Aarti, Spjelkavik A., et al. On the development of Vacuum Swing adsorption (VSA) technology for post-combustion CO2 capture. Energy Procedia 2013, 37:33-39.
143. Yazaydin A.A.O., Snurr Q.R., Park T.-H., Koh K., Liu J., LeVan M.D., et al. Screening of metal-organic frameworks for carbon dioxide capture from flue gas using a combined experimental and modeling approach. J Am Chem Soc 2009, 131:18198-18199.
144. Han S., Huang Y., Watanabe T., Nair S., Walton K.S., Sholl D.S., et al. MOF stability and gas adsorption as a function of exposure to water, humid air, SO2, and NO2. Microporous Mesoporous Mater 2013, 173:86-91.
145. Yu J., Balbuena P.B. Water effects on postcombustion CO2 capture in Mg-MOF-74. J Phys Chem 2013, 117:3383-3388.
146. Fracaroli A.M., Furukawa H., Suzuki M., Dodd M., Okajima S., Gándara F., et al. Metal-organic frameworks with precisely designed interior for carbon dioxide capture in the presence of water. J Am Chem Soc 2014.
147. Chaffee A.L., Knowles G.P., Liang Z., Zhang J., Xiao P., Webley P.A. CO2 capture by adsorption: materials and process development. Int J Greenhouse Gas Control 2007, 1:11-18.
148. Li G., Xiao P., Webley P., Zhang J., Singh R., Marshall M. Capture of CO2 from high humidity flue gas by vacuum swing adsorption with zeolite 13X. Adsorption 2008, 14:415-422.
149. Mérel J., Clausse M., Meunier F. Carbon dioxide capture by indirect thermal swing adsorption using 13X zeolite. Environ Prog 2006, 25:327-333.
150. Wang L., Yang Y., Shen W., Kong X., Li P., Yu J., et al. Experimental evaluation of adsorption technology for CO2 capture from flue gas in an existing coal-fired power plant. Chem Eng Sci 2013, 101:615-619.
151. Gomes V.G., Yee K.W. Pressure swing adsorption for carbon dioxide sequestration from exhaust gases. Sep Purif Technol 2002, 28:161-171.
152. Cho S., Park J., Beum H., Han S., Kim J. A 2-stage PSA process for the recovery of CO2 from flue gas and its power consumption. Stud Surf Sci Catal 2004, 153:405-410.
153. Zhang J., Webley P., Xiao P. Effect of process parameters on power requirements of vacuum swing adsorption technology for CO2 capture from flue gas". Energy Convers Manage 2008, 49:346-356.
154. Choi W., Kwon T., Yeo Y., Lee H., Song H. Optimal operation of the pressure swing adsorption (PSA) process for CO2 recovery. Korean J Chem Eng 2003, 20:617-623.
155. Merel J., Clausse M., Meunier F. Experimental investigation on CO2 post-combustion capture by indirect thermal swing adsorption using 13X and 5A zeolites. Ind Eng Chem Res 2008, 47(1):209-215.
156. Clausse M., Merel J., Meunier F. Numerical parametric study on CO2 capture by indirect thermal swing adsorption. Int J Greenhouse Gas Control 2011, 5:1206-1213.
157. Ribeiro R.P.P.L., Grande C.A., Rodrigues A.E. Activated carbon honeycomb monolith - Zeolite 13X hybrid system to capture CO2 from flue gases employing Electric Swing Adsorption. Chem Eng Sci 2013, 104:304-318.
158. Cavenati S., Grande C.A., Rodrigues A.E. Adsorption equilibrium of methane, carbon dioxide, and nitrogen on zeolite 13X at high pressures. J Chem Eng Data 2004, 49(4):1095-1101.
159. 2 capture by PSA: breakthrough experiments and process design. Sep Purif Technol 2013, 112(July):34-48.
160. Sipöcz N., Tobiesen F.A., Assadi M. The use of Artificial Neural Network models for CO2 capture plants. Appl Energy 2011, 88(7):2368-2376. 10.1016/j.apenergy.2011.01.013.
161. Mohsen S. Mathematical modeling of single and multi-component adsorption fixed beds to rigorously predict the mass transfer zone and breakthrough curves. Iran J Chem Chem Eng 2009, 28(3):25-44.
162. Shafeeyan M.S., Wan Daud W.M.A., Shamiri A. A review of mathematical modeling of fixed-bed columns for carbon dioxide adsorption. Chem Eng Res Des 2013, (August).
163. Ruthven D.M. Principles of adsorption and adsorption processes.pdf 1984, Wiley & Sons, New Brunswick, Fredericton. 10th ed.
164. Kim M.B., Bae Y.-S., Choi D.-K., Lee C.-H. Kinetic separation of landfill gas by a two-bed pressure swing adsorption process packed with carbon molecular sieve: nonisothermal operation. Ind Eng Chem Res 2006, 45(14):5050-5058.
165. 2 pressure swing adsorption for an aerator. Ind Eng Chem Res 2002, 41:4383-4392.
166. Rezaei F., Grahn M. Thermal management of structured adsorbents in CO2 capture processes. Ind Eng Chem Res 2012.
167. Khalighi M., Farooq S., Karimi I.A. Nonisothermal pore diffusion model for a kinetically controlled pressure swing adsorption process. Ind Eng Chem Res 2012.
168. Kumar R. Adsorption column blowdown: adiabatic equilibrium model for bulk binary gas mixtures. Ind Eng Chem Res 1989, 28(11):1677-1683.
169. Delgado J.A., Uguina M.A., Sotelo J.L., Ruíz B. Fixed-bed adsorption of carbon dioxide-helium, nitrogen-helium and carbon dioxide-nitrogen mixtures onto silicalite pellets. Sep Purif Technol 2006, 49(1):91-100.
170. Delgado J.A., Uguina M.A., Sotelo J.L., Ruíz B., Rosário M. Separation of carbon dioxide/methane mixtures by adsorption on a basic resin. Adsorption 2007, 13(3-4):373-383.
171. Shendalman L.H., Mitchell J.E. A study of heatless adsorption on the system CO2 in the He(l). Chem Eng Sci 1972, 27:1449-1458.
172. Cen P., Yang R.T. Separation of a five-component gas mixture by PSA. Sep Sci Technol 1985, 20:725.
173. Raghavan N.S., Hassan M.M., Ruthven D.M., Joboken N.J. Numerical simulation of a PSA system. Part I: isothermal trace component system with linear equilibrium and finite mass transfer resistance (1985). AIChE J 1985, 31(1985):385-392.
174. Kapoor A. Kinetic separation of methane-carbon dioxide mixture by adsorption on molecular sieve carbon. Chem Eng Sci 1989, 44(8).
175. Cavenati S., Grande C.A., Rodrigues A.E. Upgrade of methane from landfill gas by pressure swing adsorption. Energy Fuels 2005, 19(6):2545-2555.
176. Ahn H., Brandani S. Dynamics of carbon dioxide breakthrough in a carbon monolith over a wide concentration range. Adsorption 2005, 11(S1):473-477.
177. Hwang K.Y.E.S., Jun J.A.E.H.O., Lee W.O.N.K. Fixed-bed adsorption for bulk component. Chem Eng Sci 1995, 50(5).
178. Chou C.T., Chen C.-Y. Carbon dioxide recovery by vacuum swing adsorption. Sep Purif Technol 2004, 39(1-2):51-65.
179. Mulgundmath V.P., Jones R.A., Tezel F.H., Thibault J. Fixed bed adsorption for the removal of carbon dioxide from nitrogen: breakthrough behaviour and modelling for heat and mass transfer. Sep Purif Technol 2012, 85:17-27.
180. Doong S.J., Yang R.T. Bulk separation of multi-component gas mixtures by pressure swing adsorption: pore/surface diffusion and equilibrium models. AIChE J 1986, 32(3):397-410.
181. Diagne D., Gotob M., Hiroseb T. Numerical analysis of a dual refluxed PSA process during simultaneous removal and concentration of carbon dioxide dilute gas from air. J Chem Technol Biotechnol 1996, 65:29-38.
182. 2 PSA for coke oven gas. AIChE J 1999, 45(3):535-545.
183. 2 PSA process using layered beds. AIChE J 2000, 46(4):790-802.
184. Kaguei S., Wakao N. Validity of infinite bed assumption in the estimation of parameters from thermal waves measured in a non-isothermal adsorption column. Chem Eng Sci 1985, 40(10):1851-1853.
185. Hwang K.S.H., Lee W.K. The adsorption and desorption breakthrough behavior of carbon dioxide on activated carbon. effect of total pressure and pressure-dependent mass transfer coefficients. Sep Purif Technol 1994, 29(14):1857-1891.
186. Carter J.W., Husain H. The simultaneous adsorption of carbon dioxide and water vapour by fixed beds of molecular seives. Chem Eng Sci 1974, 29(1):267-273.
187. 2 adsorption on hydrotalcite adsorbent. Chem Eng Sci 2000, 55(17):3461-3474.
188. Takamura S.U.Y., Narita S., Aoik J., Hironaka S. Evaluation of double bed pressure swing adsorption for CO2 recovery from boiler gas exhaust. Elsevier Sep Purif Tachnol 2001, 24:519-528.
189. Cavenati S., Grande C.A., Rodrigues A.E. Separation of mixtures by layered pressure swing adsorption for upgrade of natural gas. Chem Eng Sci 2006, 61(12):3893-3906.
190. Moreira R.F.P.M., Soares J.L., Casarin G.L., Rodrigues A.E. Adsorption of CO2 on hydrotalcite-like compounds in a fixed bed. Sep Sci Technol 2006, 41(2):341-357.
191. Biswas P., Agrawal S., Sinha S. Modeling and simulation for pressure swing adsorption system for hydrogen purification. Chem Biochem Eng Q 2010, 24(4):409-414.
192. Agarwal A. Advanced strategies for optimal design and operation of pressure swing adsorption processes; 2010.
193. 2 mixtures on activated carbon: experiments and modeling. Adsorption 2012, 18(2):143-161.
194. Sabouni R. Carbon dioxide adsorption by metal-organic frameworks (synthesis, testing and modelling). University of Western Ontario - Electronic Thesis and Dissertation Repository. Paper 1472; 2013 http://ir.lib.uwo.ca/etd/1472.
195. 2 capture from dry flue gas by vacuum swing adsorption: a pilot plant study. AIChE J (Separations Mater Dev Process) 2014, 60(5).
196. Glueckauf E., Coates J.I. Theory of chromatography, Part IV, The influence of incomplete equilibrium on the front boundary of chromatograms and on the effectiveness of separation. J Chem Soc (Resumed) 1947, 1315-1321.
197. Bao Z., Yu L., Ren Q., Lu X., Deng S. Adsorption of CO2 and CH4 on a magnesium-based metal organic framework. J Colloid Interface Sci 2011, 353(2):549-556.
198. Saha D., Bao Z. Adsorption of CO2, CH4, N2O and N2 on MOF-5, MOF-177, and Zeolite 5A. Environ Sci Technol 2010, 44(5):1820-1826.