Bo Zhang, Bolun Yang, Wei Guo, Song Wu, Jie Zhang, Zhiqiang Wu
Bo Zhang, Bolun Yang, Wei Guo, Song Wu, Jie Zhang, Zhiqiang Wu
|  H.J. Ge, L.H. Shen, H.C. Bai, S.W. Ma, S.Y. Yin, P. Lu, T. Song, Characteristics of zhundong coal ash in hematite-based chemical looping combustion, Energy Fuels 34(7) (2020) 8150-8166.
 K.Q. Jiang, H. Yu, L.H. Chen, M.X. Fang, M. Azzi, A. Cottrell, K.K. Li, An advanced, ammonia-based combined NOx/SOx/CO2 emission control process towards a low-cost, clean coal technology, Appl. Energy 260(2020) 114316.
 National Energy Administration, 13th Five-Year Plan for Coal Industry Development, 2016.
 F.F. Hou, Current status and thinking of safe and efficient green development of coal resources, Resour. Inform. Eng. 35(1) (2020) 40-42.
 T.M. Ismail, L. Ding, K. Ramzy, Numerical and experimental analysis for simulating fuel reactor in chemical looping combustor system, J. Coal Sci. Technol 9(2020) 551-559.
 S.Y. Chang, J.K. Zhuo, S. Meng, S.Y. Qin, Q. Yao, Clean coal technologies in China:Current status and future perspectives, Engineering 2(4) (2016) 447-459.
 Z.Q. Wu, B. Zhang, S. Wu, G.M. Li, S.D. Zhao, Y.W. Li, B.L. Yang, Chemical looping gasification of lignocellulosic biomass with iron-based oxygen carrier:Products distribution and kinetic analysis on gaseous products from cellulose, Fuel Process. Technol. 193(2019) 361-371.
 L.S. Fan, L. Zeng, S.W. Luo, Chemical-looping technology platform, AIChE J. 61(1) (2015) 2-22.
 R. Wadhwani, B. Mohanty, Effects of operating pressure on the key parameters of coal direct chemical looping combustion, J. Coal Sci. Technol. 3(1) (2016) 20-27.
 Q.J. Guo, X.D. Hu, Y.Z. Liu, W.H. Jia, M.M. Yang, M. Wu, H.J. Tian, H.J. Ryu, Coal chemical-looping gasification of Ca-based oxygen carriers decorated by CaO, Powder Technol. 275(2015) 60-68.
 Q.J. Guo, Y. Cheng, Y.Z. Liu, W.H. Jia, H.J. Ryu, Coal chemical looping gasification for syngas generation using an Iron-based oxygen carrier, Ind. Eng. Chem. Res. 53(1) (2014) 78-86.
 M. Arjmand, A.M. Azad, H. Leion, T. Mattisson, A. Lyngfelt, Evaluation of CuAl2O4 as an oxygen carrier in chemical-looping combustion, Ind. Eng. Chem. Res. 51(43) (2012) 13924-13934.
 Z. Xia, W. Wang, G. Wang, Study of the crystal structure effect and mechanism during chemical looping gasification of coal, J. Energy Inst. 92(5) (2019) 1284-1293.
 J. Yang, L.P. Ma, S.L. Dong, H.P. Liu, S.Q. Zhao, X.J. Cui, D.L. Zheng, J. Yang, Theoretical and experimental demonstration of lignite chemical looping gasification of phosphogypsum oxygen carrier for syngas generation, Fuel 194(2017) 448-459.
 M. Alonso, N. Rodriguez, B. Gonzalez, G. Grasa, R. Murillo, J.C. Abanades, Carbon dioxide capture from combustion flue gases with a calcium oxide chemical loop. Experimental results and process development, Int. J. Greenh. Gas Control 4(2) (2010) 167-173.
 Y.N. Wang, X. Tian, H.B. Zhao, K.L. Liu, The use of a low-cost oxygen carrier prepared from red mud and copper ore for in situ gasification chemical looping combustion of coal, Fuel Process. Technol. 205(2020) 106460.
 M. An, J.J. Ma, W. Wu, T. Ren, X.D. Hu, Q.J. Guo, Chemical looping gasification of yangchang coalwith CuFe2O4 as oxygen carrier, Acta Petrol. Sin. 35(3) (2019) 561-568.
 X.D. Hu, Studies into Ca-based compound oxygen carriers used in chemicallooping gasification of coal, Qingdao University of Science Technology, Qingdao, 2014.
 R. Siriwardane, J. Poston, E. Monazam, E. Monazam, G. Richards, Production of hydrogen by steam oxidation of calcium ferrite reduced with various coals, Int. J. Hydrog. Energy 44(14) (2019) 7158-7167.
 J.H. Wang, J. Du, L.P. Chang, K.C. Xie, Study on the structure and pyrolysis characteristics of Chinese western coals, Fuel Process. Technol. 91(4) (2010) 430-433.
 C.Z. Li, K.D. Bartle, R. Kandiyoti, Vacuum pyrolysis of maceral concentrates in a wire-mesh reactor, Fuel 72(11) (1993) 1459-1468.
 B. Strugnell, J.W. Patrick, Rapid hydropyrolysis studies on coal and maceral concentrates, Fuel 75(3) (1996) 300-306.
 Y. Li, H. Wang, W.C. Li, Z.S. Li, N.S. Cai, CO2 Gasification of a lignite char in microfluidized bed thermogravimetric analysis for chemical looping combustion and chemical looping with oxygen uncoupling, Energy Fuels 33(1) (2019) 449-459.
 B. Bhui, P. Vairakannu, Experimental and kinetic studies on in-situ CO2 gasification based chemical looping combustion of low ash coal using Fe2O3 as the oxygen carrier, J. CO2 Util. 29(2019) 103-116.
 Y. De Vos, M. Jacobs, I. van Driessche, P. van der Voort, F. Snijkers, Processing and characterization of Fe-based oxygen carriers for chemical looping for hydrogen production, Int. J. Greenh. Gas Control 70(2018) 12-21.
 J. Zhang, Thermodynamic Simulation and Experimental Study of Chemical Looping Gasification of Coal with Cooper Ferrite as Oxygen Carriers, Southeast University, Nanjing, 2019.
 L.M. Lin, D.Y. Liu, J. Jin, Q. Cheng, W. Li, L. Feng, High iron and calcium coal ash as the oxygen carrier for chemical looping combustion, Ind. Eng. Chem. Res. 57(29) (2018) 9725-9736.
 G.X. Deng, K.Z. Li, Z.H. Gu, X. Zhu, Y.G. Wei, X.M. Cheng, H. Wang, Synergy effects of combined red muds as oxygen carriers for chemical looping combustion of methane, Chem. Eng. J. 341(2018) 588-600.
 L. Liu, Y. Cao, Q.C. Liu, J. Yang, Experimental and kinetic studies of coal-CO2 gasification in isothermal and pressurized conditions, RSC Adv. 7(4) (2017) 2193-2201.
 L.Y. Chen, J.H. Bao, L. Kong, M. Combs, H.S. Nikolic, Z. Fan, K.L. Liu, The direct solid-solid reaction between coal char and iron-based oxygen carrier and its contribution to solid-fueled chemical looping combustion, Appl. Energy 184(2016) 9-18.
 R.V. Siriwardane, E. Ksepko, H.J. Tian, J. Poston, T. Simonyi, M. Sciazko, Interaction of iron-copper mixed metal oxide oxygen carriers with simulated synthesis gas derived from steam gasification of coal, Appl. Energy 107(2013) 111-123.
 K. Wang, Q.B. Yu, Q. Qin, L.M. Hou, W.J. Duan, Thermodynamic analysis of syngas generation from biomass using chemical looping gasification method, Int. J. Hydrog. Energy 41(24) (2016) 10346-10353.
 C. Saha, S. Bhattacharya, Determination and comparison of CuO reduction/oxidation kinetics in CLC experiments with CO/air by the shrinking core model and its characterization, Energy Fuels 28(5) (2014) 3495-3510.
 Z.Q. Wu, W.C. Yang, B.L. Yang, Thermal characteristics and surface morphology of char during co-pyrolysis of low-rank coal blended with microalgal biomass:effects of nannochloropsis and chlorella, Bioresour. Technol. 249(2018) 501-509.
 Z.Q. Wu, S.Z. Wang, J. Zhao, L. Chen, H.Y. Meng, Thermal behavior and char structure evolution of bituminous coal blends with edible fungi residue during co-pyrolysis, Energy Fuels 28(3) (2014) 1792-1801.
 Z.Q. Wu, W.C. Yang, X.Y. Tian, B.L. Yang, Synergistic effects from co-pyrolysis of low-rank coal and model components of microalgae biomass, Energy Conv. Manag. 135(2017) 212-225.
 X.K. Xu, R.M. Pan, R.Y. Chen, D.D. Zhang, Comparative pyrolysis characteristics and kinetics of typical hardwood in inert and oxygenous atmosphere, Appl. Biochem. Biotechnol. 190(1) (2020) 90-112.
 F.Q. Guo, Y.P. Dong, Z.C. Lv, P.F. Fan, S. Yang, L. Dong, Pyrolysis kinetics of biomass (herb residue) under isothermal condition in a micro fluidized bed, Energy Conv. Manag. 93(2015) 367-376.
 T. Ozawa, A new method of analyzing thermogravimetric data, Bull. Chem. Soc. Jpn. 38(11) (1965) 1881-1886.
 Z.Q. Wu, W.C. Yang, Y.W. Li, B. Zhang, B.L. Yang, On-line analysis on the interaction between organic compounds from co-pyrolysis of microalgae and low-rank coal:Thermal behavior and kinetic characteristics, Bioresour. Technol. 268(2018) 672-676.
 H.J. Song, G.R. Liu, J.Z. Zhang, J.H. Wu, Pyrolysis characteristics and kinetics of low rank coals by TG-FTIR method, Fuel Process. Technol. 156(2017) 454-460.
 N. Mao, Q. Wang, Y. Yang, D. Xu, W. Feng, J. Zhang, H. Bai, Q. Guo, Pyrolysis characteristics and kinetics analysis of qinghua coal, ningxia based on chemical bonding characteristics of macerals, CIESC J. 71(2) (2020) 811-820. (in Chinese)
 H. Merdun, Z.B. Laougé, Kinetic and thermodynamic analyses during copyrolysis of greenhouse wastes and coal by TGA, Renew. Energy 163(2021) 453-464.
 Y. Xu, Y.F. Zhang, Y. Wang, G.J. Zhang, L. Chen, Gas evolution characteristics of lignite during low-temperature pyrolysis, J. Anal. Appl. Pyrolysis 104(2013) 625-631.
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