Chinese Journal of Chemical Engineering ›› 2021, Vol. 37 ›› Issue (9): 30-38.DOI: 10.1016/j.cjche.2021.03.051
• Separation Science and Engineering • Previous Articles Next Articles
Wan Zhang1, Yingjie Li1, Yuqi Qian1, Boyu Li1, Jianli Zhao1, Zeyan Wang2
Wan Zhang1, Yingjie Li1, Yuqi Qian1, Boyu Li1, Jianli Zhao1, Zeyan Wang2
|  G.P. Peters, R.M. Andrew, J.G. Canadell, P. Friedlingstein, R.B. Jackson, J.I. Korsbakken, C. Quéré, A. Peregon, Carbon dioxide emissions continue to grow amidst slowly emerging climate policies, Nat. Clim. Chang. 10(1) (2020) 3-6.
 Global CO2 Emissions in 2019, IEA, 2019. https://www.iea.org/articles/globalco2-emissions-in-2019.
 K.Y. Dong, X.C. Dong, Q.Z. Jiang, How renewable energy consumption lower global CO2 emissions? Evidence from countries with different income levels, World Econ. 43(6) (2020) 1665-1698.
 K. Yoro, P. Sekoai, The potential of CO2 capture and storage technology inSouth Africa's coal-fired thermal power plants, Environments 3(4) (2016) 24.
 V. Tola, G. Cau, F. Ferrara, A. Pettinau, CO2 emissions reduction from coal-fired power generation:A techno-economic comparison, J. Energy Resour. Technol. 138(2016) 1602-1610.
 X.T. Liu, J.F. Shi, L. He, X.X. Ma, S.S. Xu, Modification of CaO-based sorbents prepared from calcium acetate for CO2 capture at high temperature, Chin. J. Chem. Eng. 25(5) (2017) 572-580.
 C. Luo, Y. Zheng, N. Ding, Q.L. Wu, G. Bian, C.G. Zheng, Development and performance of CaO/La2O3 sorbents during calcium looping cycles for CO2 capture, Ind. Eng. Chem. Res. 49(22) (2010) 11778-11784.
 D.L. He, C.L. Qin, Z.H. Zhang, S. Pi, J.Y. Ran, G. Pu, Investigation of Y2O3/MxOyincorporated Ca-based sorbents for efficient and stable CO2 capture at high temperature, Ind. Eng. Chem. Res. 57(34) (2018) 11625-11635.
 H. Wang, Z.S. Li, Y. Li, N.S. Cai, Reduced-order model for CaO carbonation kinetics measured using micro-fluidized bed thermogravimetric analysis, Chem. Eng. Sci. 229(2021) 116039.
 J.M. Valverde, S. Medina, Reduction of calcination temperature in the calcium looping process for CO2 capture by using helium:In situ XRD analysis, ACS Sustain. Chem. Eng. 4(12) (2016) 7090-7097.
 Y. Li, Z.S. Li, H. Wang, N.S. Cai, CaO carbonation kinetics determined using micro-fluidized bed thermogravimetric analysis, Fuel 264(2020) 116823.
 D.L. He, Z.L. Ou, C.L. Qin, T. Deng, J.J. Yin, G. Pu, Understanding the catalytic acceleration effect of steam on CaCO3 decomposition by density function theory, Chem. Eng. J. 379(2020) 122348.
 M.F. Fu, C.T. Li, P. Lu, L. Qu, M.Y. Zhang, Y. Zhou, M.G. Yu, Y. Fang, A review on selective catalytic reduction of NOx by supported catalysts at 100-300℃-Catalysts, mechanism, kinetics, Catal. Sci. Technol. 4(1) (2014) 14-25.
 S.S. Feng, M.D. Zhou, F. Han, Z.X. Zhong, W.H. Xing, A bifunctional MnOx@PTFE catalytic membrane for efficient low temperature NOx-SCR and dust removal, Chin. J. Chem. Eng. 28(5) (2020) 1260-1267.
 M.W. Wang, W.Y. Meng, J. Ren, K. Zhang, F.L. Yang, F.Q. Cheng, Analysis and diagnosis of SCR denitrification system in 330 MW lean coal-fired boiler, Clean Coal Technol. 23(5) (2017) 98-104.
 H. Li, K.H. Han, H.T. Liu, C.M. Lu, Experimental and modeling study on de-NOx characteristics of selective non-catalytic reduction in O2/CO2 atmosphere, Chin. J. Chem. Eng. 22(8) (2014) 943-949.
 T. Ma, Y. Ru, K. Li, J. Hui, H. Zhu, M. Li, Study on deep denitrification performance of SNCR+SCR for a 300 MW CFB boiler, Clean Coal Technol. 26(2020) 99-105.
 X. Cheng, M. Zhang, P. Sun, L. Wang, Z. Wang, C. Ma, Nitrogen oxides reduction by carbon monoxide over semi-coke supported catalysts in a simulated rotary reactor:Reaction performance under dry conditions, Green Chem. 18(2016) 5305-5324.
 M. Kacimi, M. Ziyad, L.F. Liotta, Cu on amorphous AlPO4:Preparation, characterization and catalytic activity in NO reduction by CO in presence of oxygen, Catal. Today 241(2015) 151-158.
 P. Xiao, R.C. Davis, X.Y. Ouyang, J.L. Li, A. Thomas, S.L. Scott, J.J. Zhu, Mechanism of NO reduction by CO over Pt/SBA-15, Catal. Commun. 50(2014) 69-72.
 X. Wang, X. Wu, N. Maeda, A. Baiker, Striking activity enhancement of gold supported on Al-Ti mixed oxide by promotion with ceria in the reduction of NO with CO, Appl. Catal. B Environ. 209(2017) 62-68.
 X. Liao, J. Shao, S. Zhang, X. Li, H. Yang, X. Wang, H. Chen, Effects of CO2 and CO on the reduction of NO over calcined limestone or char in oxy-fuel fluidized bed combustion, IET Renew Power Gener. 13(2019) 1633-1640.
 D. Allen, A.N. Hayhurst, The effect of CaO on emissions of nitric oxide from a fluidised bed combustor, Fuel 158(2015) 898-907.
 J. Krzywanski, T. Czakiert, T. Shimizu, I. Majchrzak-Kuceba, Y. Shimazaki, A. Zylka, K. Grabowska, M. Sosnowski, NOx emissions from regenerator of calcium looping process, Energy Fuels 32(5) (2018) 6355-6362.
 C.Y. Gao, T. Higuchi, A. Yoshizawa, T. Shimizu, H. Kim, L.Y. Li, Role of char in NOx formation during coal combustion at a regenerator temperature of calcium looping process, Fuel 121(2014) 319-326.
 J. Hilz, M. Helbig, M. Haaf, A. Daikeler, J. Ströhle, B. Epple, Investigation of the fuel influence on the carbonate looping process in 1 MWth scale, Fuel Process. Technol. 169(2018) 170-177.
 C.Y. Gao, T. Takahashi, H. Narisawa, A. Yoshizawa, T. Shimizu, H. Kim, L.Y. Li, Coal combustion under calcium looping process conditions, Fuel 127(2014) 38-46.
 T. Shimizu, Y. Matsuura, A. Yoshizawa, Y. Shimazaki, T. Shimoda, H. Kim, L. Li, Reduction of NOx by char under condition for carbonator of calcium looping CO2 capture process, J. Jpn. Inst. Energy 94(2015) 841-850.
 W. Zhang, Y.J. Li, X.T. Ma, Y.Q. Qian, Z.Y. Wang, Simultaneous NO/CO2 removal performance of biochar/limestone in calcium looping process, Fuel 262(2020) 116428.
 W. Zhang, Y.J. Li, B.Y. Li, Y.Z. Wang, Y.Q. Qian, Z.Y. Wang, Simultaneous NO/CO2 removal by Cu-modified biochar/CaO in carbonation step of calcium looping process, Chem. Eng. J. 392(2020) 123659.
 H. Wang, Z.S. Li, N.S. Cai, Multiscale model for steam enhancement effect on the carbonation of CaO particle, Chem. Eng. J. 394(2020) 124892.
 J. Chen, L. Duan, Z. Sun, Accurate control of cage-like CaO hollow microspheres for enhanced CO2 capture in calcium looping via a template-assisted synthesis approach, Environ. Sci. Technol. 53(4) (2019) 2249-2259.
 T. Furusawa, M. Tsunoda, M. Tsujimura, T. Adschiri, Nitric oxide reduction by char and carbon monoxide:Fundamental kinetics of nitric oxide reduction in fluidized bed combustion of coal, Fuel 64(1985) 1306-1309.
 L.K. Chan, A.F. Sarofim, J.M. Beér, Kinetics of the NO-carbon reaction at fluidized bed combustor conditions, Combust. Flame 52(1983) 37-45.
 A. Coppola, F. Montagnaro, P. Salatino, F. Scala, Fluidized bed calcium looping:The effect of SO2 on sorbent attrition and CO2 capture capacity, Chem. Eng. J. 207-208(2012) 445-449.
 A. Coppola, F. Montagnaro, P. Salatino, F. Scala, Attrition of limestone during fluidized bed calcium looping cycles for CO2 capture, Combust. Sci. Technol. 184(7-8) (2012) 929-941.
 A. Charitos, N. Rodríguez, C. Hawthorne, M. Alonso, M. Zieba, B. Arias, G. Kopanakis, G. Scheffknecht, J.C. Abanades, Experimental validation of the calcium looping CO2 capture process with two circulating fluidized bed carbonator reactors, Ind. Eng. Chem. Res. 50(16) (2011) 9685-9695.
 A. Coppola, F. Scala, L. Gargiulo, P. Salatino, A twin-bed test reactor for characterization of calcium looping sorbents, Powder Technol. 316(2017) 585-591.
 J. Chen, L.B. Duan, F. Donat, C.R. Müller, E.J. Anthony, M.H. Fan, Self-activated, nanostructured composite for improved CaL-CLC technology, Chem. Eng. J. 351(2018) 1038-1046.
 J. Chen, L.B. Duan, T. Shi, R.Y. Bian, Y.X. Lu, F. Donat, E.J. Anthony, A facile onepot synthesis of CaO/CuO hollow microspheres featuring highly porous shells for enhanced CO2 capture in a combined Ca-Cu looping process via a templatefree synthesis approach, J. Mater. Chem. A 7(37) (2019) 21096-21105.
 L. Dong, S.Q. Gao, W.L. Song, G.W. Xu, Experimental study of NO reduction over biomass char, Fuel Process. Technol. 88(7) (2007) 707-715.
 E. Kadossov, U. Burghaus, Adsorption kinetics and dynamics of CO, NO, and CO2 on reduced CaO(100), J. Phys. Chem. C 112(19) (2008) 7390-7400.
 T. Shimizu, K. Ito, S. Shizuno, R. Houshito, T. Shimoda, H. Tsukahara, L.Y. Li, Reaction pathways of NOX and N2O over CaO in the presence of char under carbonator conditions of calcium-looping CO2 capture process, J. Jpn. Inst. Energy 95(12) (2016) 1115-1124.
 T. Shimizu, T. Shimoda, R. Houshito, H. Kato, O. Hara, L.Y. Li, N2O reduction and NOx adsorption in carbonator of calcium looping CO2 capture process, J. Jpn. Inst. Energy 96(7) (2017) 228-238.
 F. Voigts, F. Bebensee, S. Dahle, K. Volgmann, W. Maus-Friedrichs, The adsorption of CO2 and CO on Ca and CaO films studied with MIES, UPS and XPS., Surf. Sci. 603(1) (2009) 40-49.
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