Carbon Dioxide Capture and Storage: A General Review on Adsorbents
CO2 is the primary anthropogenic greenhouse gas,
accounting for 77% of the human contribution to the greenhouse
effect in 2004. In the recent years, global concentration of CO2 in the
atmosphere is increasing rapidly. CO2 emissions have an impact on
global climate change. Anthropogenic CO2 is emitted primarily from
fossil fuel combustion. Carbon capture and storage (CCS) is one
option for reducing CO2 emissions. There are three major approaches
for CCS: post-combustion capture, pre-combustion capture and
oxyfuel process. Post-combustion capture offers some advantages as
existing combustion technologies can still be used without radical
changes on them.
There are several post combustion gas separation and capture
technologies being investigated, namely; (a) absorption, (b)
cryogenic separation, (c) membrane separation (d) micro algal biofixation
and (e) adsorption. Apart from establishing new techniques,
the exploration of capture materials with high separation performance
and low capital cost are paramount importance. However, the
application of adsorption from either technology, require easily
regenerable and durable adsorbents with a high CO2 adsorption
capacity. It has recently been reported that the cost of the CO2
capture can be reduced by using this technology. In this paper, the
research progress (from experimental results) in adsorbents for CO2
adsorption, storage, and separations were reviewed and future
research directions were suggested as well.
[1] Zangeneh, F.T., S. Sahebdelfar, and M.T. Ravanchi, "Conversion of
carbon dioxide to valuable petrochemicals: An approach to clean
development mechanism," Journal of Natural Gas Chemistry. 20(3): p.
219-231. 2011.
[2] Li, G., P. Xiao, P.A. Webley, J. Zhang, and R. Singh, "Competition of
CO2/H2O in adsorption based CO2 capture," Energy Procedia. 1(1): p.
1123-1130. 2009.
[3] Thiruvenkatachari, R., S. Su, H. An, and X.X. Yu, "Post combustion
CO2 capture by carbon fibre monolithic adsorbents," Progress in Energy
and Combustion Science. 35(5): p. 438-455. 2009.
[4] Dantas, T.L.P., F.M.T. Luna, I.J. Silva Jr, A.E.B. Torres, D.C.S.
Azevedo, A.E. Rodrigues, and R.F.P.M. Moreira, "Carbon dioxide-
nitrogen separation through pressure swing adsorption," Chemical
Engineering Journal. 172(2-3): p. 698-704. 2011.
[5] Choi, S., J.H. Drese, and C.W. Jones, "Adsorbent Materials for Carbon
Dioxide Capture from Large Anthropogenic Point Sources,"
ChemSusChem. 2(9): p. 796-854. 2009.
[6] Dechamps, P., CO2 Capture and Storage Projects, E. 22574, Editor.
2007.
[7] Maroto-Valer, M.M., Z. Tang, and Y. Zhang, "CO2 capture by activated
and impregnated anthracites," Fuel Processing Technology. 86(14-15):
p. 1487-1502. 2005.
[8] Garnier, C., G. Finqueneisel, T. Zimny, Z. Pokryszka, S. Lafortune,
P.D.C. Défossez, and E.C. Gaucher, "Selection of coals of different
maturities for CO2 Storage by modelling of CH4 and CO2 adsorption
isotherms," International Journal of Coal Geology. 87(2): p. 80-86.
2011.
[9] Li, J.-R., Y. Ma, M.C. McCarthy, J. Sculley, J. Yu, H.-K. Jeong, P.B.
Balbuena, and H.-C. Zhou, "Carbon dioxide capture-related gas
adsorption and separation in metal-organic frameworks," Coordination
Chemistry Reviews. 255(15-16): p. 1791-1823. 2011.
[10] Plaza, M.G., S. García, F. Rubiera, J.J. Pis, and C. Pevida, "Postcombustion
CO2 capture with a commercial activated carbon:
Comparison of different regeneration strategies," Chemical Engineering
Journal. 163(1-2): p. 41-47. 2010.
[11] Damen, K., M.v. Troost, A. Faaij, and W. Turkenburg, "A comparison
of electricity and hydrogen production systems with CO2 capture and
storage. Part A: Review and selection of promising conversion and
capture technologies," Progress in Energy and Combustion Science.
32(2): p. 215-246. 2006.
[12] Grande, C.A., R.P.L. Ribeiro, E.L.G. Oliveira, and A.E. Rodrigues,
"Electric swing adsorption as emerging CO2 capture technique," Energy
Procedia. 1(1): p. 1219-1225. 2009.
[13] Sahebdelfar, S., F. Tahriri Zangeneh, and M. Takht Ravanchi, Chemical
Recycling of Carbon Dioxide to Valuable Petrochemicals, in The 7th
APCSEET conference. 2009: Qingdao, China.
[14] Takht Ravanchi, M., S. Sahebdelfar, and F. Tahriri Zangeneh, Carbon
Dioxide Sequestration in Petrochemical Industries with the Aim of
Reduction in Greenhouse Gas Emissions, in The 7th APCSEET
conference. 2009: Qingdao, China. p. 173-178.
[15] Wang, M., A. Lawal, P. Stephenson, J. Sidders, and C. Ramshaw, "Postcombustion
CO2 capture with chemical absorption: A state-of-the-art
review," Chemical Engineering Research and Design. 89(9): p. 1609-
1624. 2011.
[16] Pellerano, M., P. Pré, M. Kacem, and A. Delebarre, "CO2 capture by
adsorption on activated carbons using pressure modulation," Energy
Procedia. 1(1): p. 647-653. 2009.
[17] Chaffee, A.L., G.P. Knowles, Z. Liang, J. Zhang, P. Xiao, and P.A.
Webley, "CO2 capture by adsorption: Materials and process
development," International Journal of Greenhouse Gas Control. 1(1):
p. 11-18. 2007.
[18] Chiao, C.-H., J.-L. Chen, C.-R. Lan, S. Chen, and H.-W. Hsu,
"Development of carbon dioxide capture and storage technology -
taiwan power company perspective," Sustain. Environ. Res. 21(1): p. 1-
8. 2011.
[19] Feron, P.H.M., "Exploring the potential for improvement of the energy
performance of coal fired power plants with post-combustion capture of
carbon dioxide," International Journal of Greenhouse Gas Control.
4(2): p. 152-160. 2010.
[20] Clausse, M., J. Merel, and F. Meunier, "Numerical parametric study on
CO2 capture by indirect thermal swing adsorption," International
Journal of Greenhouse Gas Control. 5(5): p. 1206-1213. 2011.
[21] Serna-Guerrero, R. and A. Sayari, "Modeling adsorption of CO2 on
amine-functionalized mesoporous silica. 2: Kinetics and breakthrough
curves," Chemical Engineering Journal. 161(1-2): p. 182-190. 2010.
[22] Pevida, C., M.G. Plaza, B. Arias, J. Fermoso, F. Rubiera, and J.J. Pis,
"Surface modification of activated carbons for CO2 capture," Applied
Surface Science. 254(22): p. 7165-7172. 2008.
[23] Zhang, J., P. Xiao, G. Li, and P.A. Webley, "Effect of flue gas
impurities on CO2 capture performance from flue gas at coal-fired
power stations by vacuum swing adsorption," Energy Procedia. 1(1): p.
1115-1122. 2009.
[24] Martunus, Z. Helwani, A.D. Wiheeb, J. Kim, and M.R. Othman,
"Improved carbon dioxide capture using metal reinforced hydrotalcite
under wet conditions," International Journal of Greenhouse Gas
Control. 7(0): p. 127-136. 2012.
[25] Meng, L.-Y. and S.-J. Park, "Influence of MgO template on carbon
dioxide adsorption of cation exchange resin-based nanoporous carbon,"
Journal of Colloid and Interface Science. 366(1): p. 125-129. 2012.
[26] Sevilla, M. and A.B. Fuertes, "CO2 adsorption by activated templated
carbons," Journal of Colloid and Interface Science. 366(1): p. 147-154.
2012.
[27] Lee, Z.H., K.T. Lee, S. Bhatia, and A.R. Mohamed, "Post-combustion
carbon dioxide capture: Evolution towards utilization of nanomaterials,"
Renewable and Sustainable Energy Reviews. 16(5): p. 2599-2609. 2012.
[28] Herzog, H., J. Meldon, and A. Hatton, Advanced Post-Combustion CO2
Capture. 2009.
[29] Besson, R., M. Rocha Vargas, and L. Favergeon, "CO2 adsorption on
calcium oxide: An atomic-scale simulation study," Surface Science.
606(3-4): p. 490-495. 2012.
[30] Essaki, K., M. Kato, and K. Nakagawa, "CO2 removal at high
temperature using packed bed of lithium silicate pellets.," Journal of the
Ceramic Society of Japan. 114:7: p. 39-42. 2006.
[31] Anbia, M. and V. Hoseini, "Development of MWCNT@MIL-101
hybrid composite with enhanced adsorption capacity for carbon
dioxide," Chemical Engineering Journal. 191(0): p. 326-330. 2012.
[32] Wang, J., L.A. Stevens, T.C. Drage, and J. Wood, "Preparation and CO2
adsorption of amine modified Mg-Al LDH via exfoliation route,"
Chemical Engineering Science. 68(1): p. 424-431. 2012.
[33] Sakurovs, R., S. Day, and S. Weir, "Relationships between the sorption
behaviour of methane, carbon dioxide, nitrogen and ethane on coals,"
Fuel. 97(0): p. 725-729. 2012.
[34] Weniger, P., J. Franců, P. Hemza, and B.M. Krooss, "Investigations on
the methane and carbon dioxide sorption capacity of coals from the SW
Upper Silesian Coal Basin, Czech Republic," International Journal of
Coal Geology. 93(0): p. 23-39. 2012.
[35] Shafeeyan, M.S., W.M.A. Wan Daud, A. Houshmand, and A. Arami-
Niya, "The application of response surface methodology to optimize the
amination of activated carbon for the preparation of carbon dioxide
adsorbents," Fuel. 94(0): p. 465-472. 2012.
[36] Plaza, M.G., C. Pevida, B. Arias, J. Fermoso, F. Rubiera, and J.J. Pis, "A
comparison of two methods for producing CO2 capture adsorbents,"
Energy Procedia. 1(1): p. 1107-1113. 2009.
[37] Siriwardane, R.V., M.-S. Shen, E.P. Fisher, and J.A. Poston,
"Adsorption of CO2 on Molecular Sieves and Activated Carbon,"
Energy & Fuels. 15(2): p. 279-284. 2001.
[38] Vatalis, K.I., A. Laaksonen, G. Charalampides, and N.P. Benetis,
"Intermediate technologies towards low-carbon economy. The Greek
zeolite CCS outlook into the EU commitments," Renewable and
Sustainable Energy Reviews. 16(5): p. 3391-3400. 2012.
[39] Cui, X., R.M. Bustin, and G. Dipple, "Selective transport of CO2, CH4,
and N2 in coals: insights from modeling of experimental gas adsorption
data," Fuel. 83(3): p. 293-303. 2004.
[40] Jang, D.-I. and S.-J. Park, "Influence of nickel oxide on carbon dioxide
adsorption behaviors of activated carbons," Fuel. (0). 2012.
[41] Abid, H.R., G.H. Pham, H.-M. Ang, M.O. Tade, and S. Wang,
"Adsorption of CH4 and CO2 on Zr-metal organic frameworks,"
Journal of Colloid and Interface Science. 366(1): p. 120-124. 2012.
[42] Xiang, Z., Z. Hu, D. Cao, W. Yang, J. Lu, B. Han, and W. Wang,
"Metal-Organic Frameworks with Incorporated Carbon Nanotubes:
Improving Carbon Dioxide and Methane Storage Capacities by Lithium
Doping," Angewandte Chemie International Edition. 50(2): p. 491-494.
2011.
[43] Liu, Z., C.A. Grande, P. Li, J. Yu, and A.E. Rodrigues, "Multi-bed
Vacuum Pressure Swing Adsorption for carbon dioxide capture from
flue gas," Separation and Purification Technology. 81(3): p. 307-317.
2011.
[44] Zhang, J., R. Singh, and P.A. Webley, "Alkali and alkaline-earth cation
exchanged chabazite zeolites for adsorption based CO2 capture,"
Microporous and Mesoporous Materials. 111(1-3): p. 478-487. 2008.
[45] Deng, H., H. Yi, X. Tang, Q. Yu, P. Ning, and L. Yang, "Adsorption
equilibrium for sulfur dioxide, nitric oxide, carbon dioxide, nitrogen on
13X and 5A zeolites," Chemical Engineering Journal. 188(0): p. 77-85.
2012.
[46] Yang, R., G. Liu, M. Li, J. Zhang, and X. Hao, "Preparation and N2,
CO2 and H2 adsorption of super activated carbon derived from biomass
source hemp (Cannabis sativa L.) stem," Microporous and Mesoporous
Materials. 158(0): p. 108-116. 2012.
[47] Alca├▒iz-Monge, J., D. Cazorla-Amor├│s, A. Linares-Solano, S. Yoshida,
and A. Oya, "Effect of the activating gas on tensile strength and pore
structure of pitch-based carbon fibres," Carbon. 32(7): p. 1277-1283.
1994.
[48] Gargiulo, N., F. Pepe, and D. Caputo, "Modeling carbon dioxide
adsorption on polyethylenimine-functionalized TUD-1 mesoporous
silica," Journal of Colloid and Interface Science. 367(1): p. 348-354.
2012.
[49] Millward, A.R. and O.M. Yaghi, "Metal−Organic Frameworks with
Exceptionally High Capacity for Storage of Carbon Dioxide at Room
Temperature," Journal of the American Chemical Society. 127(51): p.
17998-17999. 2005.
[50] Lin, L.-Y. and H. Bai, "Continuous generation of mesoporous silica
particles via the use of sodium metasilicate precursor and their potential
for CO2 capture," Microporous and Mesoporous Materials. 136(1-3): p.
25-32. 2010.
[51] Mishra, A.K. and S. Ramaprabhu, "Palladium nanoparticles decorated
graphite nanoplatelets for room temperature carbon dioxide adsorption,"
Chemical Engineering Journal. 187(0): p. 10-15. 2012.
[52] Aziz, B., N. Hedin, and Z. Bacsik, "Quantification of chemisorption and
physisorption of carbon dioxide on porous silica modified by
propylamines: Effect of amine density," Microporous and Mesoporous
Materials. 159(0): p. 42-49. 2012.
[53] Chen, C., J. Kim, and W.-S. Ahn, "Efficient carbon dioxide capture over
a nitrogen-rich carbon having a hierarchical micro-mesopore structure,"
Fuel. 95(0): p. 360-364. 2012.
[1] Zangeneh, F.T., S. Sahebdelfar, and M.T. Ravanchi, "Conversion of
carbon dioxide to valuable petrochemicals: An approach to clean
development mechanism," Journal of Natural Gas Chemistry. 20(3): p.
219-231. 2011.
[2] Li, G., P. Xiao, P.A. Webley, J. Zhang, and R. Singh, "Competition of
CO2/H2O in adsorption based CO2 capture," Energy Procedia. 1(1): p.
1123-1130. 2009.
[3] Thiruvenkatachari, R., S. Su, H. An, and X.X. Yu, "Post combustion
CO2 capture by carbon fibre monolithic adsorbents," Progress in Energy
and Combustion Science. 35(5): p. 438-455. 2009.
[4] Dantas, T.L.P., F.M.T. Luna, I.J. Silva Jr, A.E.B. Torres, D.C.S.
Azevedo, A.E. Rodrigues, and R.F.P.M. Moreira, "Carbon dioxide-
nitrogen separation through pressure swing adsorption," Chemical
Engineering Journal. 172(2-3): p. 698-704. 2011.
[5] Choi, S., J.H. Drese, and C.W. Jones, "Adsorbent Materials for Carbon
Dioxide Capture from Large Anthropogenic Point Sources,"
ChemSusChem. 2(9): p. 796-854. 2009.
[6] Dechamps, P., CO2 Capture and Storage Projects, E. 22574, Editor.
2007.
[7] Maroto-Valer, M.M., Z. Tang, and Y. Zhang, "CO2 capture by activated
and impregnated anthracites," Fuel Processing Technology. 86(14-15):
p. 1487-1502. 2005.
[8] Garnier, C., G. Finqueneisel, T. Zimny, Z. Pokryszka, S. Lafortune,
P.D.C. Défossez, and E.C. Gaucher, "Selection of coals of different
maturities for CO2 Storage by modelling of CH4 and CO2 adsorption
isotherms," International Journal of Coal Geology. 87(2): p. 80-86.
2011.
[9] Li, J.-R., Y. Ma, M.C. McCarthy, J. Sculley, J. Yu, H.-K. Jeong, P.B.
Balbuena, and H.-C. Zhou, "Carbon dioxide capture-related gas
adsorption and separation in metal-organic frameworks," Coordination
Chemistry Reviews. 255(15-16): p. 1791-1823. 2011.
[10] Plaza, M.G., S. García, F. Rubiera, J.J. Pis, and C. Pevida, "Postcombustion
CO2 capture with a commercial activated carbon:
Comparison of different regeneration strategies," Chemical Engineering
Journal. 163(1-2): p. 41-47. 2010.
[11] Damen, K., M.v. Troost, A. Faaij, and W. Turkenburg, "A comparison
of electricity and hydrogen production systems with CO2 capture and
storage. Part A: Review and selection of promising conversion and
capture technologies," Progress in Energy and Combustion Science.
32(2): p. 215-246. 2006.
[12] Grande, C.A., R.P.L. Ribeiro, E.L.G. Oliveira, and A.E. Rodrigues,
"Electric swing adsorption as emerging CO2 capture technique," Energy
Procedia. 1(1): p. 1219-1225. 2009.
[13] Sahebdelfar, S., F. Tahriri Zangeneh, and M. Takht Ravanchi, Chemical
Recycling of Carbon Dioxide to Valuable Petrochemicals, in The 7th
APCSEET conference. 2009: Qingdao, China.
[14] Takht Ravanchi, M., S. Sahebdelfar, and F. Tahriri Zangeneh, Carbon
Dioxide Sequestration in Petrochemical Industries with the Aim of
Reduction in Greenhouse Gas Emissions, in The 7th APCSEET
conference. 2009: Qingdao, China. p. 173-178.
[15] Wang, M., A. Lawal, P. Stephenson, J. Sidders, and C. Ramshaw, "Postcombustion
CO2 capture with chemical absorption: A state-of-the-art
review," Chemical Engineering Research and Design. 89(9): p. 1609-
1624. 2011.
[16] Pellerano, M., P. Pré, M. Kacem, and A. Delebarre, "CO2 capture by
adsorption on activated carbons using pressure modulation," Energy
Procedia. 1(1): p. 647-653. 2009.
[17] Chaffee, A.L., G.P. Knowles, Z. Liang, J. Zhang, P. Xiao, and P.A.
Webley, "CO2 capture by adsorption: Materials and process
development," International Journal of Greenhouse Gas Control. 1(1):
p. 11-18. 2007.
[18] Chiao, C.-H., J.-L. Chen, C.-R. Lan, S. Chen, and H.-W. Hsu,
"Development of carbon dioxide capture and storage technology -
taiwan power company perspective," Sustain. Environ. Res. 21(1): p. 1-
8. 2011.
[19] Feron, P.H.M., "Exploring the potential for improvement of the energy
performance of coal fired power plants with post-combustion capture of
carbon dioxide," International Journal of Greenhouse Gas Control.
4(2): p. 152-160. 2010.
[20] Clausse, M., J. Merel, and F. Meunier, "Numerical parametric study on
CO2 capture by indirect thermal swing adsorption," International
Journal of Greenhouse Gas Control. 5(5): p. 1206-1213. 2011.
[21] Serna-Guerrero, R. and A. Sayari, "Modeling adsorption of CO2 on
amine-functionalized mesoporous silica. 2: Kinetics and breakthrough
curves," Chemical Engineering Journal. 161(1-2): p. 182-190. 2010.
[22] Pevida, C., M.G. Plaza, B. Arias, J. Fermoso, F. Rubiera, and J.J. Pis,
"Surface modification of activated carbons for CO2 capture," Applied
Surface Science. 254(22): p. 7165-7172. 2008.
[23] Zhang, J., P. Xiao, G. Li, and P.A. Webley, "Effect of flue gas
impurities on CO2 capture performance from flue gas at coal-fired
power stations by vacuum swing adsorption," Energy Procedia. 1(1): p.
1115-1122. 2009.
[24] Martunus, Z. Helwani, A.D. Wiheeb, J. Kim, and M.R. Othman,
"Improved carbon dioxide capture using metal reinforced hydrotalcite
under wet conditions," International Journal of Greenhouse Gas
Control. 7(0): p. 127-136. 2012.
[25] Meng, L.-Y. and S.-J. Park, "Influence of MgO template on carbon
dioxide adsorption of cation exchange resin-based nanoporous carbon,"
Journal of Colloid and Interface Science. 366(1): p. 125-129. 2012.
[26] Sevilla, M. and A.B. Fuertes, "CO2 adsorption by activated templated
carbons," Journal of Colloid and Interface Science. 366(1): p. 147-154.
2012.
[27] Lee, Z.H., K.T. Lee, S. Bhatia, and A.R. Mohamed, "Post-combustion
carbon dioxide capture: Evolution towards utilization of nanomaterials,"
Renewable and Sustainable Energy Reviews. 16(5): p. 2599-2609. 2012.
[28] Herzog, H., J. Meldon, and A. Hatton, Advanced Post-Combustion CO2
Capture. 2009.
[29] Besson, R., M. Rocha Vargas, and L. Favergeon, "CO2 adsorption on
calcium oxide: An atomic-scale simulation study," Surface Science.
606(3-4): p. 490-495. 2012.
[30] Essaki, K., M. Kato, and K. Nakagawa, "CO2 removal at high
temperature using packed bed of lithium silicate pellets.," Journal of the
Ceramic Society of Japan. 114:7: p. 39-42. 2006.
[31] Anbia, M. and V. Hoseini, "Development of MWCNT@MIL-101
hybrid composite with enhanced adsorption capacity for carbon
dioxide," Chemical Engineering Journal. 191(0): p. 326-330. 2012.
[32] Wang, J., L.A. Stevens, T.C. Drage, and J. Wood, "Preparation and CO2
adsorption of amine modified Mg-Al LDH via exfoliation route,"
Chemical Engineering Science. 68(1): p. 424-431. 2012.
[33] Sakurovs, R., S. Day, and S. Weir, "Relationships between the sorption
behaviour of methane, carbon dioxide, nitrogen and ethane on coals,"
Fuel. 97(0): p. 725-729. 2012.
[34] Weniger, P., J. Franců, P. Hemza, and B.M. Krooss, "Investigations on
the methane and carbon dioxide sorption capacity of coals from the SW
Upper Silesian Coal Basin, Czech Republic," International Journal of
Coal Geology. 93(0): p. 23-39. 2012.
[35] Shafeeyan, M.S., W.M.A. Wan Daud, A. Houshmand, and A. Arami-
Niya, "The application of response surface methodology to optimize the
amination of activated carbon for the preparation of carbon dioxide
adsorbents," Fuel. 94(0): p. 465-472. 2012.
[36] Plaza, M.G., C. Pevida, B. Arias, J. Fermoso, F. Rubiera, and J.J. Pis, "A
comparison of two methods for producing CO2 capture adsorbents,"
Energy Procedia. 1(1): p. 1107-1113. 2009.
[37] Siriwardane, R.V., M.-S. Shen, E.P. Fisher, and J.A. Poston,
"Adsorption of CO2 on Molecular Sieves and Activated Carbon,"
Energy & Fuels. 15(2): p. 279-284. 2001.
[38] Vatalis, K.I., A. Laaksonen, G. Charalampides, and N.P. Benetis,
"Intermediate technologies towards low-carbon economy. The Greek
zeolite CCS outlook into the EU commitments," Renewable and
Sustainable Energy Reviews. 16(5): p. 3391-3400. 2012.
[39] Cui, X., R.M. Bustin, and G. Dipple, "Selective transport of CO2, CH4,
and N2 in coals: insights from modeling of experimental gas adsorption
data," Fuel. 83(3): p. 293-303. 2004.
[40] Jang, D.-I. and S.-J. Park, "Influence of nickel oxide on carbon dioxide
adsorption behaviors of activated carbons," Fuel. (0). 2012.
[41] Abid, H.R., G.H. Pham, H.-M. Ang, M.O. Tade, and S. Wang,
"Adsorption of CH4 and CO2 on Zr-metal organic frameworks,"
Journal of Colloid and Interface Science. 366(1): p. 120-124. 2012.
[42] Xiang, Z., Z. Hu, D. Cao, W. Yang, J. Lu, B. Han, and W. Wang,
"Metal-Organic Frameworks with Incorporated Carbon Nanotubes:
Improving Carbon Dioxide and Methane Storage Capacities by Lithium
Doping," Angewandte Chemie International Edition. 50(2): p. 491-494.
2011.
[43] Liu, Z., C.A. Grande, P. Li, J. Yu, and A.E. Rodrigues, "Multi-bed
Vacuum Pressure Swing Adsorption for carbon dioxide capture from
flue gas," Separation and Purification Technology. 81(3): p. 307-317.
2011.
[44] Zhang, J., R. Singh, and P.A. Webley, "Alkali and alkaline-earth cation
exchanged chabazite zeolites for adsorption based CO2 capture,"
Microporous and Mesoporous Materials. 111(1-3): p. 478-487. 2008.
[45] Deng, H., H. Yi, X. Tang, Q. Yu, P. Ning, and L. Yang, "Adsorption
equilibrium for sulfur dioxide, nitric oxide, carbon dioxide, nitrogen on
13X and 5A zeolites," Chemical Engineering Journal. 188(0): p. 77-85.
2012.
[46] Yang, R., G. Liu, M. Li, J. Zhang, and X. Hao, "Preparation and N2,
CO2 and H2 adsorption of super activated carbon derived from biomass
source hemp (Cannabis sativa L.) stem," Microporous and Mesoporous
Materials. 158(0): p. 108-116. 2012.
[47] Alca├▒iz-Monge, J., D. Cazorla-Amor├│s, A. Linares-Solano, S. Yoshida,
and A. Oya, "Effect of the activating gas on tensile strength and pore
structure of pitch-based carbon fibres," Carbon. 32(7): p. 1277-1283.
1994.
[48] Gargiulo, N., F. Pepe, and D. Caputo, "Modeling carbon dioxide
adsorption on polyethylenimine-functionalized TUD-1 mesoporous
silica," Journal of Colloid and Interface Science. 367(1): p. 348-354.
2012.
[49] Millward, A.R. and O.M. Yaghi, "Metal−Organic Frameworks with
Exceptionally High Capacity for Storage of Carbon Dioxide at Room
Temperature," Journal of the American Chemical Society. 127(51): p.
17998-17999. 2005.
[50] Lin, L.-Y. and H. Bai, "Continuous generation of mesoporous silica
particles via the use of sodium metasilicate precursor and their potential
for CO2 capture," Microporous and Mesoporous Materials. 136(1-3): p.
25-32. 2010.
[51] Mishra, A.K. and S. Ramaprabhu, "Palladium nanoparticles decorated
graphite nanoplatelets for room temperature carbon dioxide adsorption,"
Chemical Engineering Journal. 187(0): p. 10-15. 2012.
[52] Aziz, B., N. Hedin, and Z. Bacsik, "Quantification of chemisorption and
physisorption of carbon dioxide on porous silica modified by
propylamines: Effect of amine density," Microporous and Mesoporous
Materials. 159(0): p. 42-49. 2012.
[53] Chen, C., J. Kim, and W.-S. Ahn, "Efficient carbon dioxide capture over
a nitrogen-rich carbon having a hierarchical micro-mesopore structure,"
Fuel. 95(0): p. 360-364. 2012.
@article{"International Journal of Chemical, Materials and Biomolecular Sciences:59990", author = "Mohammad Songolzadeh and Maryam Takht Ravanchi and Mansooreh Soleimani", title = "Carbon Dioxide Capture and Storage: A General Review on Adsorbents", abstract = "CO2 is the primary anthropogenic greenhouse gas,
accounting for 77% of the human contribution to the greenhouse
effect in 2004. In the recent years, global concentration of CO2 in the
atmosphere is increasing rapidly. CO2 emissions have an impact on
global climate change. Anthropogenic CO2 is emitted primarily from
fossil fuel combustion. Carbon capture and storage (CCS) is one
option for reducing CO2 emissions. There are three major approaches
for CCS: post-combustion capture, pre-combustion capture and
oxyfuel process. Post-combustion capture offers some advantages as
existing combustion technologies can still be used without radical
changes on them.
There are several post combustion gas separation and capture
technologies being investigated, namely; (a) absorption, (b)
cryogenic separation, (c) membrane separation (d) micro algal biofixation
and (e) adsorption. Apart from establishing new techniques,
the exploration of capture materials with high separation performance
and low capital cost are paramount importance. However, the
application of adsorption from either technology, require easily
regenerable and durable adsorbents with a high CO2 adsorption
capacity. It has recently been reported that the cost of the CO2
capture can be reduced by using this technology. In this paper, the
research progress (from experimental results) in adsorbents for CO2
adsorption, storage, and separations were reviewed and future
research directions were suggested as well.", keywords = "Carbon capture and storage, pre-combustion, postcombustion,
adsorption", volume = "6", number = "10", pages = "946-8", }
