Chemical looping processes - Particle characterization, ionic diffusion-reaction mechanism and reactor engineering

Reviews in Chemical Engineering

Volumn 28, Issue 1, 2012, Pages 1-42

  Zeng, Liang ^a   Luo, Siwei ^a   Sridhar, Deepak ^a   Fan, Liang Shih ^a  

^a Ohio State University   (United States)

Author keywords

Chemical looping; Combustion; Gasifi cation; Ionic diffusion; Reactor engineering

Indexed keywords

CHEMICAL LOOPING; CHEMICAL-LOOPING PROCESS; CONTACT MODES; DIFFUSION-REACTION; ENERGY CONVERSION SYSTEMS; FOSSIL ENERGY; IONIC DIFFUSION; METAL CARBONATES; METAL OXIDES; PARTICLE CHARACTERIZATION; PREPARATION METHOD; RATE PROCESS; REACTANT CONVERSION; REACTION MECHANISM; REACTOR ENGINEERING; REDUCTION-OXIDATION; SOLID REACTANTS; TECHNOLOGY PERFORMANCE; TYPE II;

CALCINATION; COMBUSTION; DIFFUSION IN SOLIDS; ENERGY CONVERSION; HYDROGEN; METALLIC COMPOUNDS; QUANTUM CHEMISTRY; REACTION INTERMEDIATES;

IODINE;

EID: 84859757788     PISSN: 01678299     EISSN: None     Source Type: Journal    
DOI: 10.1515/revce-2011-0010     Document Type: Review

References (167)

1. Abad A, Mattisson T, Lyngfelt A, Johansson M. The use of iron oxide as oxygen carrier in a chemical-looping reactor. Fuel 2007; 86: 1021-1035. (Pubitemid 46096484)
2. Abanades JC. Experimental investigation of a CFB reactor to capture CO2 from flue gases with CaO. Presented at: the First IEA GHG High Temperature Solid Looping Cycles Network Meeting, Oviedo, Spain, 2009.
3. Abanades JC, Alvarez D. Conversion limits in the reaction of CO2 with lime. Energ Fuel 2003; 17: 308-315.
4. Abanades JC, Rodriguez N, Gonzalez B, Grasa G, Murillo R. Capturing CO2 from combustion flue gases with a carbonationcalcination loop. Experimental results and process development. Proceedings of the 9th International Conference on Greenhouse Gas Control Technologies (GHGT-9), Nov 16-20, 2008; Washington, DC, USA. Energ Procedia 2009; 1: 1147-1154.
5. Adanez J, de Diego LF, Garcia-Labiano F, Gayan P, Abad A, Palacios JM. Selection of oxygen carriers for chemical-looping combustion. Energ Fuel 2004; 18: 371-377.
6. Adánez J, Gayán P, Celaya J, de Diego L, García-Labiano F, Abad A. Chemical looping combustion in a 10 kWth prototype using a CuO/Al2O3 oxygen carrier: effect of operating conditions on methane combustion. Ind Eng Chem Res 2006; 45: 6075-6080. (Pubitemid 44343103)
7. Albrecht KO, Wagenbach KS, Satrio JA, Shanks BH, Wheelock TD. Development of a CaO-based CO2 sorbent with improved cyclic stability. Ind Eng Chem Res 2008; 47: 7841-7848.
8. Andrus HE Jr, Burns G, Chiu JH, Liljedahl GN. (Alstom Power Inc). (Jun). Hybrid combustion-gasiflcation chemical looping power technology development. Phase II flnal report. Washington, DC: US Department of Energy, 2006. Contract No.: DE-FC26-03NT41866.
9. ARPA-E website: http://arpa-e.energy.gov/ProgramsProjects/Other Projects/CarbonCapture/PilotScaleTestingofCarbonNegative ProductFl.aspx, 2010. Accessed on 1 October, 2011.
10. Avrami M. Grand partition functions and so-called" Thermodynamic probability."J Chem Phys 1939; 7: 3-108.
11. Avrami M. Kinetics of phase change. II Transformation-time relations for random distribution of nuclei. J Chem Phys 1940; 8: 212-225.
12. Avrami M. Granulation, phase change, and microstructure kinetics of phase change. J Chem Phys 1941; 9: 177-185.
13. Balasubramaniam B, Lopez Ortiz A, Kaytakoglu S, Harrison DP. Hydrogen from methane in a single step. Chem Eng Sci 1999; 54: 3543-3552.
14. Béal C, Epple B, Lyngfelt A, Adanez J, Larring Y, Guillemont A, Anheden M. Development of metal oxides chemical looping process for coal-flred power plants. Presented at: the 1st International Conference on Chemical Looping, Lyon, France, 2010.
15. Benton AF, Emmett PH. The reduction of nickelous and ferric oxides by hydrogen. J Am Chem Soc 1924; 46: 2728.
16. Berguerand N, Lyngfelt A. Design and operation of a 10 KWth chemical-looping combustor for solid fuels-testing with South African coal. Fuel 2008a; 87: 2713-2726.
17. Berguerand N, Lyngfelt A. The use of petroleum coke as fuel in a 10 KWth chemical-looping combustor. Int J Greenhouse Gas Control 2008b; 2: 169-179.
18. Berguerand N, Lyngfelt A. Chemical-looping combustion of petroleum coke using ilmenite in a 10 kWth unit-high-temperature operation. Energ Fuel 2009; 23: 5257-5268.
19. Berguerand N, Lyngfelt A. Batch testing of solid fuels with ilmenite in a 10 kWth chemical-looping combustor. Fuel 2010; 89: 1749-1762.
20. Berguerand N, Lyngfelt A, Mattisson T, Markström P. Chemicallooping combustion of solid fuels in a 10 kWth unit. Oil Gas Sci Technol 2011; 66: 181-191.
21. Bhatia SK, Perlmutter DD. Effect of the product later on kinetics of the CO2 -lime reaction. AIChE J 1983; 29: 79-86. (Pubitemid 13490221)
22. Bi HT, Fan LS. Existence of turbulent regime in gas-solid fluidization. AIChE J 1992; 32: 297-301.
23. Bi HT, Grace JR. Flow regime diagrams for gas-solid fluidization and upward transport. Int J Multiphase Flow 1995; 21: 1229-1236.
24. Bi HT, Grace JR, Zhu J. Regime transitions affecting gas-solids suspensions and fluidized-beds. Chem Eng Res Des 1995; 73: 154-161.
25. Biljetina R, Tarman PB. Development of the steam-iron process for hydrogen production. Chicago: Institute of Gas Technology, 1979.
26. Birss FW, Thorvaldson T. The mechanism of the hydration of calcium oxide. Can J Chem 1955; 33: 881-886.
27. Blamey J, Wang J, Fennell PS. The calcium looping cycle for largescale CO2 capture. Prog Energ Combust 2010; 36: 260-279.
28. Boldyrev VV. Control of the reactivity of solids. Annu Rev Mater Sci 1979; 9: 455-469.
29. Bolhàr-Nordenkampf J, Proll T, Kolbitsch P, Hofbauer H. Performance of a NiO-based oxygen carrier for chemical looping combustion and reforming in a 120 kW unit. Proceedings of the 9th International Conference on Greenhouse Gas Control Technologies (GHGT-9), Nov 16-20, 2008; Washington, DC, USA. Energ Procedia 2009; 1: 19-25.
30. Brun-Tsekhovoi AR, Zadorin AN, Katsobashvili YR, Kourdyumov SS. The process of catalytic steam reforming of hydrocarbons in the presence of a carbon dioxide acceptor. Hydrocarbon energy progress VII. Proceedings of the 7th World Hydrogen Energy Conference, 1986, Moscow, Russia. New York: Pergamon Press, 1988, pp. 885-900.
31. Butt DP, Lackner KS, Wendt CH, Conzone SD, Kung H, Lu YC, Bremser JK. Kinetics of thermal dehydroxylation and carbonation of magnesium hydroxide. J Am Ceram Soc 1996; 79: 1892-1898. (Pubitemid 126588793)
32. Charitos A, Hawthorne C, Bidwe AR, Sivalingam S, Schuster A. Parametric investigation of the calcium looping process for CO2 capture in a 10kWth dual fluidized bed. Int J Greenhouse Gas Control 2010; 4: 776-784.
33. Chen Z, Song HS, Portillo M, Lim CJ, Grace JR, Anthony EJ. Longterm calcination/carbonation cycling and thermal pretreatment for CO2 capture by limestone and dolomite. Energ Fuel 2009; 23: 1437-1444.
34. Chiang YM, Birnie III DP, Kingery WD. Physical ceramics-principles for ceramic science and engineering. New York, USA: John Wiley & Sons Inc, 1997.
35. Chiesa P, Kreutz TG, Lozza GG. CO2 sequestration from IGCC power plants by means of metallic membranes. J Eng Gas Turb Power 2007; 129: 123-134. (Pubitemid 46738707)
36. Cho P, Mattisson T, Lyngfelt A. Comparison of iron-, nickel-, copper-and manganese-based oxygen carriers for chemical-looping combustion. Fuel 2004; 83: 1215-1225.
37. Cooley RF, Reed JS. Equilibrium cation distribution in NiAl 2O4 , CuAl 2O4 , and ZnAl 2O4 spinels. J Am Ceram Soc 2006; 55: 395-398.
38. Darken LS, Gurry RW. The system iron-oxygen. 1. The wustite fleld and related equilibria. J Am Chem Soc 1945; 67: 1398-1412.
39. Dean CC, Blamey J, Florin NH, Al-Jeboori MJ, Fennell PS. The calcium looping cycle for CO2 capture from power generation, cement manufacture and hydrogen production. Chem Eng Res Des 2011; 89: 836-855.
40. de Diego LF, Gayán P, García-Labiano F, Celaya J, Abad A, Adánez J. Impregnated CuO/Al 2O3 oxygen carriers for chemical-looping combustion: avoiding fluidized bed agglomeration. Energ Fuel 2005; 19: 1850-1856.
41. de Diego LF, Garcia-Labiano F, Gayan P, Celaya J, Palacios JM, Adanez J. Operation of a 10 kWth chemical-looping combustor during 200 h with a CuO-Al 2O3 oxygen carrier. Fuel 2007; 86: 1036-1045. (Pubitemid 46096493)
42. Dobbyn RC, Ondik HM, Willard WA, Brower WS, Feinberg IJ, Hahn TA, Hicho GE, Read ME, Robbins CR, Smith JH. (Continental Oil Co, Library, PA). An evaluation of the performance of materials and components used in the CO2 acceptor process gasiflcation pilot plant. Technical report. Washington, DC: US Department of Energy, 1978. Report No.: DOE-ET-10253-T1. Contract No.: AC01-76ET10253.
43. Dorman W. Flash calcination of limestone dust and flnes. Pit Quarry 1978; 64: 52-53.
44. Edstrom JO. Solid state diffusion in the reduction of hematite. Communication from the research organization of Jernkontoret. Jernkontorets Ann 1957; 141: 809-836.
45. Eyring EM, Konya G, Lighty JS, Sahir AH, Saroflm AF, Whitty K. Chemical looping with copper oxide as carrier and coal as fuel. Oil Gas Sci Technol 2011; 66: 209-221.
46. Fan LS. Chemical looping systems for fossil energy conversions. New York, USA: Wiley, 2010.
47. Fan LS, Li F. Clean coal. Phys World 2007; 20: 37-41.
48. Fan LS, Li F. Utilization of chemical looping strategy in coal gasifl-cation processes. Particuology 2008; 6: 131-142. (Pubitemid 351763916)
49. Fan LS, Li F. Chemical looping technology and its fossil energy conversion applications. Ind Eng Chem Res 2010; 49: 10200-10211.
50. Fan LS, Zhu C. Principles of gas-solids flows. New York, USA: Cambridge University Press, 1998.
51. Fan LS, Ramkumar S, Wang W, Statnick R. Separation of carbon dioxide from gas mixtures by calcium based reaction separation process. US Provisional Patent Application 61/116172, 2008.
52. Ghosh-Dastidar A, Mahuli S, Agnihotri R, Fan LS. Ultrafast calcination and sintering of Ca(OH) 2 powder: experimental and modeling. Chem Eng Sci 1995; 50: 2029-2040.
53. Glasson DR. Reactivity of lime and related oxides. II. Sorption of water vapor on calcium oxide. J Appl Chem 1958; 8: 798-803.
54. Glasson DR. Reactivity of lime and related oxides. III. Sorption of liquid water on calcium oxide (wet hydration). J Appl Chem 1960; 10: 38-42.
55. Gueret C, Daroux M, Billaud F. Methane pyrolysis: thermodynamics. Chem Eng Sci 1997; 52: 815-827. (Pubitemid 27108766)
56. Gupta H, Fan LS. Carbonation-calcination cycle using high reactivity calcium oxide for carbon dioxide separation from flue gas. Ind Eng Chem Res 2002; 41: 4035-4042. (Pubitemid 34836794)
57. Gupta P, Velazquez-Vargas LG, Fan LS. Syngas redox (SGR) process to produce hydrogen from coal derived syngas. Energ Fuel 2007a; 21: 2900-2908. (Pubitemid 47595617)
58. Gupta P, Velazquez-Vargas LG, Fan LS. Moving bed reactor setup to study complex gas-solid reactions. Rev Sci Instrum 2007b; 78: 085106-1-085106-7.
59. Han YS, Li JB, Ning X, Yang X, Chi B. Study on NiO excess in preparing NiAl 2O4 . Mater Sci Eng A 2004; 369: 241-244.
60. Han LW, Ma Q, Guan J, Luo Z, Cen F. Hydration reactivation of CaO-based sorbent for cyclic calcination-carbonation reactions. Proceedings of the 20th International Conference on Fluidized Bed Combustion, 2009. Xi'an, China; Berlin: Springer, 2010; pp. 726-731.
61. Hauffe K. Reaktionen in und an festen Stoffen. Berlin, Germany: Springer, 1955.
62. He F, Li H, Zhao Z. Advancements in development of chemicallooping combustion: a review. Int J Chem Eng 2009; 16: 1-17.
63. Hoteit A Jr, Surla K, Yazdanpannah MM, Rifflart S, Gauthier T. Operation of a new 10kW CLC unit with independent solid flow control. Presented at: Proceedings of the AIChE Annual Meeting, Salt Lake City, UT, USA, 2010.
64. Hoteit A Jr, Forret A, Pelletant W, Roesler J, Gauthier T. Chemical looping combustion with different types of liquid fuels. Oil Gas Sci Technol 2011; 66: 193-199.
65. Huang CH, Chang KD, Yu CT, Chiang PC, Wang CF. Development of high-temperature CO2 sorbents made of CaO-based mesoporous silica. Chem Eng J 2010; 161: 129-135.
66. Hughes RW, Lu DY, Anthony EJ, Macchi A. Design, process simulation and construction of an atmospheric dual fluidized bed combustion system for in situ CO2 capture using high-temperature sorbents. Fuel Process Technol 2005; 86: 1523-1531.
67. Ishida M, Zheng D, Akehata T. Evaluation of a chemical-loopingcombustion power-generation system by graphic exergy analysis. Energy 1987; 12: 147-154. (Pubitemid 17603738)
68. Iyer M, Gupta H, Sakadjian BB, Fan LS. Multicyclic study on the simultaneous carbonation and sulfation of high-reactivity CaO. Ind Eng Chem Res 2004; 43: 3939-3947. (Pubitemid 38859269)
69. Iyer M, Ramkumar S, Wong D. Enhanced hydrogen production with in-situ CO2 capture in a single stage reactor. Paper presented at: Proceedings of the 23rd Annual International Pittsburgh Coal Conference, Pittsburgh, PA, USA, 2006.
70. Jerndal E, Leion H, Axelsson L, Ekvall T, Hedberg M, Johansson K, Källén M, Svensson R, Mattisson T, Lyngfelt A. Using low-cost iron-based materials as oxygen carriers for chemical-looping combustion. Oil Gas Sci Technol 2011; 66: 235-248.
71. Jin HG, Okamoto T, Ishida M. Development of a novel chemicallooping combustion: synthesis of a solid looping material of NiO/NiAl 2O4 . Ind Eng Chem Res 1999; 38: 126-132. (Pubitemid 29133085)
72. Johansson M. Screening of oxygen-carrier particles based on iron-, manganese-, copper-and nickel oxides for use in chemical-looping technologies [dissertation]. Göteborg, Sweden: Chalmers University, 2007.
73. Johansson M, Mattisson T, Lyngfelt A. Investigation of Fe 2O3 with MgAl 2O4 for chemical-looping combustion. Ind Eng Chem Res 2004; 43: 6978-6987.
74. Johansson E, Mattisson T, Lyngfelt A, Thunman J. A 300 W laboratory reactor system for chemical-looping combustion with particle circulation. Fuel 2006a; 85: 1428-1438.
75. Johansson M, Mattisson T, Lyngfelt A. Use of NiO/NiAl 2O4 particles in a 10 kW chemical-looping combustor. Ind Eng Chem Res 2006b; 45: 5911-5919. (Pubitemid 44343088)
76. Johnsen K, Ryu HJ, Grace JR, Lim CJ. Sorption-enhanced steam reforming of methane in a fluidized bed reactor with dolomite as CO2 -capture. Chem Eng Sci 2006; 61: 1195-1202. (Pubitemid 43005252)
77. Kim JY, Rodriguez JA, Hanson JC, Frenkel AI, Lee PL. Reduction of CuO and Cu 2 O with H 2 : H embedding and kinetic effects in the formation of suboxides. J Am Chem Soc 2003; 125: 10684-10692. (Pubitemid 37055922)
78. Kirk RE, Othmer DF. Kirk-Othmer concise encyclopedia of chemical technology. In: Kirk RE, Othmer DF, Grayson M, Echroth D, editors. 3rd ed., New York, USA: Wiley-Interscience, 1985.
79. Kleut DV. On the preparation and properties of manganese oxide based combustion catalysts [dissertation]. The Netherlands: Utrecht University, 1994.
80. Koga Y, Bamford CH, Tipper CF. Comprehensive chemical kinetics. Amsterdam, The Netherlands: Elsevier, 1984.
81. Kolbitsch P, Pröll T, Bolhàr-Nordenkampf J, Hofbauer H. Design of a chemical looping combustor using a dual circulating fluidized bed reactor system. Chem Eng Technol 2009a; 32: 398-403.
82. Kolbitsch P, Pröll T, Bolhàr-Nordenkampf J, Hofbauer H. Operating experience with chemical looping combustion in a 120kW dual circulating fluidized bed (DCFB) unit. Proceedings of the 9th International Conference on Greenhouse Gas Control Technologies (GHGT-9), Nov 16-20, 2008; Washington, DC, USA. Energ Procedia 2009b; 1: 1465-1472.
83. Kunii D, Levenspiel O. Fluidization engineering. Stoneham, MA, USA: Butterworth-Heinemann, 1991.
84. Lane H. Process for the production of hydrogen. US Patent 1,078,686, Nov 18, 1913.
85. Lawall TR. Flash calcining applied to limestone. Rock Prod 1978; 81: 82-84.
86. Leion H, Mattisson T, Lyngfelt A. The use of petroleum coke as fuel in chemical-looping combustion. Fuel 2007; 86: 1947-1958. (Pubitemid 46776662)
87. Leion H, Mattisson T, Lyngfelt A. Using chemical-looping with oxygen uncoupling (CLOU) for combustion of six different solid fuels. Proceedings of the 9th International Conference on Greenhouse Gas Control Technologies (GHGT-9), Nov 16-20, 2008; Washington, DC, USA. Energ Procedia 2009; 1: 447-453.
88. Lewis WK, Gilliland ER. Conversion of hydrocarbons with suspended catalyst. US Patent 2,498,088, Feb 21, 1950.
89. Lewis WK, Gilliland ER. Production of pure carbon dioxide. US Patent 2,665,971, Jan 12, 1954.
90. Lewis WK, Gilliland ER, Reed WA. Reaction of methane with copper oxide in a fluidized bed. Ind Eng Chem Res 1949; 41: 1227-1237.
91. Lewis WK, Gilliland ER, Reed WA. Gasiflcation of carbon, metal oxides in a fluidized powder bed. Chem Eng Prog 1951; 47: 251-256.
92. Li F, Fan LS. Clean coal conversion processes-progress and challenges. Energy Environ Sci 2008; 1: 248-267.
93. Li ZS, Cai NS, Huang YY, Han HJ. Synthesis, experimental studies, and analysis of a new calcium-based carbon dioxide absorbent. Energ Fuel 2005; 19: 1447-1452.
94. Li ZS, Cai NS, Huang YY. Effect of preparation temperature on cyclic CO2 capture and multiple carbonation-calcination cycles for a new Ca-based CO2 sorbent. Ind Eng Chem Res 2006; 45: 1911-1917.
95. Li YZ, Qu C, Duan L, Li Q, Liang C. CO2 capture using CaO modifled with ethanol/water solution during cyclic calcination/carbonation. Chem Eng Technol 2008; 31: 237-244. (Pubitemid 351278827)
96. Li F, Kim H, Sridhar D, Wang F, Zeng L, Fan LS. Syngas chemical looping gasiflcation process: oxygen carrier particle selection and performance. Energ Fuel 2009a; 23: 4182-4189.
97. Li LK, Nie Z, Howard C. Magnesia-stabilized calcium oxide absorbents with improved durability for high temperature CO2 capture. Ind Eng Chem Res 2009b; 48: 10604-10613.
98. Li F, Zeng L, Fan LS. Biomass direct chemical looping process: process simulation. Fuel 2010a; 89: 3773-3784.
99. Li F, Zeng L, Velazquez-Vargas LG, Yoscovits Z, Fan LS. Syngas chemical looping gasiflcation process: bench scale studies and reactor simulations. AIChE J 2010b; 56: 2186-2199.
100. Li F, Luo S, Sun Z, Bao X, Fan LS. Role of metal oxide support in redox reactions of iron oxide for chemical looping applications: experiments and density functional theory calculations. Energy Environ Sci 2011a; 4: 3661-3667.
101. Li F, Sun Z, Luo S, Fan LS. Ionic diffusion in iron oxidation-effect of support and its implications to chemical looping applications. Energy Environ Sci 2011b; 4: 876-880.
102. Linderholm C, Abad A, Mattisson T, Lynyfelt A. 160 h of chemical-looping combustion in a 10 kW reactor system with a NiObased oxygen carrier. Int J Greenhouse Gas Control 2008; 2: 520-530.
103. Liu QY, Wu WL, Wang J. Characterization of 12-tungstophosphoric acid impregnated on mesoporous silica SBA-15 and its catalytic performance in isopropylation of naphthalene with isopropanol. Micropor Mesopor Mat 2004; 76: 51-60. (Pubitemid 39470997)
104. Liu W, Low NW, Feng B, Diniz da Costa JC, Wang GX. Calcium precursors for the production of CaO sorbents for multi-cycle CO2 capture. Environ Sci Technol 2010; 44: 841-847.
105. Lu H, Reddy EP, Smirniotis PG. Calcium oxide based sorbents for capture of carbon dioxide at high temperatures. Ind Eng Chem Res 2006; 45: 3944-3949. (Pubitemid 44012125)
106. Lu DY, Hughes RW, Anthony EJ. Ca-based sorbent looping combustion for CO2 capture in pilot-scale dual fluidized beds. Fuel Process Technol 2008a; 89: 1386-1395.
107. Lu H, Khan A, Smirniotis PG. Relationship between structural properties and CO2 capture performance of CaO-based sorbents obtained from different organometallic precursors. Ind Eng Chem Res 2008b; 47: 6216-6220.
108. Lyngfelt A. Oxygen carriers for chemical looping combustion -4000 h of operational experience. Oil Gas Sci Technol 2011; 66: 161-172.
109. Lyngfelt A, Thunman H. Construction and 100 h of operational experience of a 10-kW chemical looping combustor. In: Thomas D, editor. The CO2 capture and storage project (CCP) for carbon dioxide storage in deep geologic formations for climate change mitigation, volume 1-capture and separation of carbon dioxide from combustion sources. London: Elsevier Science, 2005; pp. 625-645.
110. Manovic V, Anthony EJ. Long-term behavior of CaO-based pellets supported by calcium aluminate cements in a long series of CO2 capture cycles. Ind Eng Chem Res 2009; 48: 8906-8912.
111. Martavaltzi CS, Lemonidou AA. Development of new CaO based sorbent materials for CO2 removal at high temperature. Micropor Mesopor Mat 2008; 110: 119-127. (Pubitemid 351221062)
112. Mattisson T, Jardnas A, Lyngfelt A. Reactivity of some metal oxides supported on alumina with alternating methane and oxygen-application for chemical-looping combustion. Energ Fuel 2003; 17: 643-651.
113. Mattisson T, Johansson M, Lyngfelt A. Multicycle reduction and oxidation of different types of iron oxide particles-application to chemical-looping combustion. Energ Fuel 2004; 18: 628-637.
114. Mattisson T, Lyngfelt A, Leion H. Chemical-looping with oxygen uncoupling for combustion of solid fuels. Int J Greenhouse Gas Control 2009; 3: 11-19.
115. Messerschmitt A. Process for producing hydrogen. US Patent 971,206, Sep 27, 1910.
116. Milman V, Winkler B, White JA, Pickard CJ, Payne MC, Akhmatskaya EV, Nobes RH. Electronic structure, properties, and phase stability of inorganic crystals: a pseudopotential plane-wave study. Int J Quantum Chem 2000; 77: 895-910.
117. Mrowec S, Grzesik Z. Oxidation of nickel and transport properties of nickel oxide. J Phys Chem Solids 2004; 65: 1651-1657.
118. O'Keeffe M, Bovin JO. The crystal structure of paramelaconite. Am Mineral 1978: 63: 180-185.
119. Okuma N, Funayama Y, Ito H, Mizutani N, Kato M. Adsorption and reaction of CO2 gas on the surface of zinc oxide flne particles in the atmosphere. Hyomen Kagaku 1988; 9: 452-458.
120. Ortiz M, de Diego LF, Abad A, García-Labiano F, Gayán P, Adánez J. Hydrogen production by auto-thermal chemical-looping reforming in a pressurised fluidized bed reactor using Ni-based oxygen carriers. Int J Hydrogen Energ 2010; 35: 151-160.
121. Park AHA, Jadhav R, Fan LS. CO2 mineral sequestration: chemically enhanced aqueous carbonation of serpentine. Can J Chem Eng 2003; 81: 885-890. (Pubitemid 38765695)
122. Prisedsky VV, Vinogradov VM. Fragmentation of diffusion zone in high-temperature oxidation of copper. J Solid State Chem 2004; 177: 4258-4268.
123. Pröll T, Hofbauer H. A dual fluidized bed system for chemical looping combustion of solid fuels. In: AIChE, editor. Proceedings of the 2010 AIChE Annual Meeting. Nov 9, 2010; Salt Lake City, UT, USA: Omnipress.
124. Pröll T, Kolbitsch P, Bolhàr-Nordenkampf J, Hofbauer H. A novel dual fluidized circulating bed (DCFB) system for chemical looping process. AIChE J 2009a; 55: 3255-3266.
125. Pröll T, Mayer K, Bolhàr-Nordenkampf J, Kolbitsch P, Mattisson T, Lyngfelt A, Hofbauer H. Natural minerals as oxygen carriers for chemical looping combustion in a dual circulating fluidized bed system. Proceedings of the 9th International Conference on Greenhouse Gas Control Technologies (GHGT-9), Nov 16-20, 2008; Washington DC, USA. Energy Procedia 2009b; 1: 27-34.
126. Pröll T, Rupanovits K, Kolbitsch P, Bolhàr-Nordenkampf J, Hofbauer H. Cold flow model study on a dual circulating fluidized bed (DCFB) system for chemical looping processes. Chem Eng Technol 2009c; 32: 418-424.
127. Ramachandran VS, Sereda PJ, Feldman RF. Mechanism of hydration of calcium oxide. Nature 1964; 201: 288-289.
128. Ramkumar S, Fan LS. Calcium looping process (CLP) for enhanced noncatalytic hydrogen production with integrated carbon dioxide capture. Energ Fuel 2010; 24: 4408-4418.
129. Ramkumar S, Iyer M, Fan LS. Calcium looping process for enhanced catalytic hydrogen production with integrated carbon dioxide capture and sulfur capture. Ind Eng Chem Res 2011; 50: 1716-1729.
130. Readman JE, Olafsen A, Smith JB, Blom R. Chemical looping combustion using NiO/NiAl 2O4 : mechanisms and kinetics of reduction-oxidation (red-ox) reactions from in situ powder x-ray diffraction and thermogravimetry experiments. Energ Fuel 2006; 20: 1382-1387. (Pubitemid 44193551)
131. Richardson JT, Scates R, Twigg MV. X-ray diffraction study of nickel oxide reduction by hydrogen. Appl Catal A: Gen 2003; 246: 137-150.
132. Richter HJ, Knoche KF. Reversibility of combustion process. In: Gaggioli RA, editor. Efflciency and costing, second law analysis of process. ACS Symposium Series 235, Washington DC: American Chemical Society, 1983; pp. 71-85.
133. Ryden M, Lyngfelt A. Using steam reforming to produce hydrogen with carbon dioxide capture by chemical-looping combustion. Int J Hydrogen Energ 2006; 31: 1271-1283. (Pubitemid 43851166)
134. Ryden M, Lyngfelt A, Mattisson T, Chen D, Holmen A, Bjorgum E. Novel oxygen-carrier materials for chemical-looping combustion and chemical-looping reforming; La xSr1-x FeyCo1-yO3-z perovskites and mixed-metal oxides of NiO, Fe 2O3 and Mn 3O4 . Int J Greenhouse Gas Control 2008; 2: 21-36.
135. Ryu HJ, Seo Y, Jin GT. Development of chemical-looping combustion technology: long-term operation of a 50 kWth chemical-looping combustor with Ni-and Co-based oxygen carrier particles. In: Proceedings of the Regional Symposium on Chemical Engineering. Dec 4-6. 2005; Hanoi, Vietnam.
136. Sakata K, Nakamura T, Misono M, Yoneda Y. Reduction-oxidation mechanism of oxide catalysts-oxygen diffusion during redox cycles. Chem Lett 1979; 8: 273-276.
137. Sakata K, Ueda F, Misono M, Yoneda Y. Catalytic properties of ironoxides: 2. Isotopic exchange of oxygen, oxidation of carbonmonoxide, and reduction-oxidation mechanism. B Chem Soc Jpn 1980; 53: 324-329. (Pubitemid 11422398)
138. Sawada Y, Murakami M, Nishide T. Thermal analysis of basic zinc carbonate: 1. carbonation process of zinc oxide powders at 8 and 13 degrees C. Thermochim Acta 1996; 273: 95-102. (Pubitemid 126315966)
139. Scott SA, Dennis JS, Hayhurst AN, Brown T. In situ gasiflcation of a solid fuel and CO2 separation using chemical looping. AIChE J 2006; 52: 3325-3328. (Pubitemid 44368717)
140. Shaheen WM, Selim MM. Effect of thermal treatment on physicochemical properties of pure and mixed manganese carbonate and basic copper carbonate. Thermochim Acta 1998; 322: 117-128. (Pubitemid 128351286)
141. Shen L, Wu J, Gao Z, Xiao J. Reactivity deterioration of NiO/Al 2O3 oxygen carrier for chemical looping combustion of coal in a 10kW th reactor. Combust Flame 2009a; 156: 1377-1385.
142. Shen L, Wu J, Xiao J. Experiments on chemical looping combustion of coal with a NiO based oxygen carrier. Combust Flame 2009b; 156: 721-728.
143. Shen L, Wu J, Xiao J, Song Q, Xiao R. Chemical-looping combustion of biomass in a 10kW th reactor with iron oxide as an oxygen carrier. Energ Fuel 2009c; 23: 2498-2505.
144. Shimizu T, Hirama T, Hosoda H, Kitano K, Inagaki M, Tejima K. A twin fluid-bed reactor for removal of CO2 from combustion processes. Trans IChemE 1999; 77: 62-68. (Pubitemid 29365825)
145. Shulman A, Mattisson T, Lyngfelt A. Manganese/iron, manganese/ nickel, and manganese/silicon oxides used in chemical-looping with oxygen uncoupling (CLOU) for combustion of methane. Energ Fuel 2009; 23: 5269-5275.
146. Simell PA, Leppalahti JK, Bredenberg JB. Catalytic puriflcation of tarry fuel gas with carbonate rocks and ferrous materials. Fuel 1992; 71: 211-218.
147. Siriwardane R, Tian H, Miller D, Richards G, Simonyi T, Poston J. Evaluation of reaction mechanism of coal-metal oxide interactions in chemical-looping combustion. Combust Flame 2010; 157: 2198-2208.
148. Steinsvik S, Larring Y, Norby T. Hydrogen ion conduction in ironsubstituted strontium titanate, SrTi1-xFexO3-x/2(0 ≤x≤0.8). Solid State Ionics 2001; 143: 103-116. (Pubitemid 32546660)
149. Stobbe ER, de Boer BA, Geus JW. The reduction and oxidation behaviour of manganese oxides. Catal Today 1999; 47: 161-167. (Pubitemid 129603093)
150. Strohle J, Orth M, Epple B. Simulation of the fuel reactor of a 1 MWth chemical looping plant for coal. In: Proceedings of 1st International Conference on Chemical Looping. March 2010; Lyon, France.
151. Takenaka S, Kaburagi T, Yamada C, Nomura K, Otsuka K. Storage and supply of hydrogen by means of the redox of the iron oxides modifled with Mo and Rh species. J Catal 2004; 228: 66-74.
152. Thomas T, Fan LS, Gupta P, Velazquez-Vargas LG. Combustion looping using composite oxygen carriers. US Patent 7,767,191, approved date: Aug 3, 2010; priority date: Dec 11, 2003.
153. Urasaki K, Sekine Y, Tanimoto N, Tamura E, Kikuchi E, Matsukata M. Effect of a small amount of zirconia additive on the activity and stability of iron oxide during repeated redox cycles. Chem Lett 2005a; 34: 230-231. (Pubitemid 40592041)
154. Urasaki K, Tanimoto N, Hayashi T, Sekine Y, Kikuchi E, Matsukata M. Hydrogen production via steam-iron reaction using iron oxide modifled with very small amounts of palladium and zirconia. Appl Catal A Gen 2005b; 288: 143-148.
155. Velazquez-Vargas LG, Thomas T, Gupta P, Fan LS. Hydrogen production via redox reaction of syngas with metal oxide composite particles. In: Proceedings of 2004 AIChE Annual Technical Meeting. Nov 7-12, 2004; Austin, TX, USA.
156. Wang X, Hanson JC, Frenkel AI, Kim JY, Rodriguez JA. Timeresolved studies for the mechanism of reduction of copper oxides with carbon monoxide: complex behavior of lattice oxygen and the formation of suboxides. J Phys Chem B 2004; 108: 13667-13673.
157. Wang XH, Li JG, Kamiyama H, Katada M, Ohashi N, Moriyoshi Y, Ishigaki T. Pyrogenic iron(III)-doped TiO 2 nanopowders synthesized in RF thermal plasma: phase formation, defect structure, band gap, and magnetic properties. J Am Chem Soc 2005; 127: 10982-10990. (Pubitemid 41129874)
158. Wang S, Wang G, Jiang F, Luo M, Li H. Chemical looping combustion of coke oven gas by using Fe 2O3 /CuO with MgAl 2O4 as oxygen carrier. Energy Environ Sci 2010a; 9: 1353-1360.
159. Wang W, Ramkumar S, Li S, Wong D, Iyer M, Sakadjian BB, Statnick RM, Fan LS. Subpilot demonstration of the carbonation-calcination reaction (CCR) process: high-temperature CO2 and sulfur capture from coal-flred power plants. Ind Eng Chem Res 2010b; 49: 5094-5101.
160. Wang W, Ramkumar S, Wong D, Fan LS. Simulations and process analysis of the carbonation-calcination reaction process with intermediate hydration. Fuel 2011. doi:10.1016/j.fuel.2011.06.059.
161. Wu SF, Li QH, Kim JN, Yi KB. Properties of a nano CaO/Al 2O3 CO2 sorbent. Ind Eng Chem Res 2008; 47: 180-184.
162. Yang F, Choi Y, Liu P, Hrbek J, Rodriguez JA. Autocatalytic reduction of a Cu 2 O/Cu(111) surface by CO: STM, XPS, and DFT studies. J Phys Chem C 2010; 114: 17042-17050.
163. Yu FC, Phalak N, Sun Z, Fan LS. Activation strategies for calciumbased sorbents for CO2 capture-a perspective. Ind Eng Chem Res 2011; doi:10.1021/ie200802y.
164. Zafar Q, Mattisson T, Gevert B. Integrated hydrogen and power production with CO2 capture using chemical-looping reforming redox reactivity of particles of CuO, Mn 2O3 , NiO, and Fe 2O3 using SiO 2 as a support. Ind Eng Chem Res 2005; 44: 3485-3496.
165. Zhao Y, Shadman F. Kinetics and mechanism of ilmenite reduction with carbon-monoxide. AIChE J 1990; 36: 1433-1438.
166. Zhao Y, Shadman F. Reduction of ilmenite with hydrogen. Ind Eng Chem Res 1991; 30: 2080-2087. (Pubitemid 21697277)
167. Zhu Y, Mimura K, Isshiki M. Oxidation mechanism of Cu 2 O to CuO at 600-1050 °C. Oxid Met 2004; 62: 3-4.