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Review

Nickel-based catalysts for tar reduction in biomass gasification

Chunfei Wu Energy & Resources Research Institute, The University of Leeds, Leeds, LS2 9JT, UK
&
Paul T Williams[email protected]
Pages 451-464 | Published online: 09 Apr 2014

Bibliography

  • Mckendry P. Energy production from biomass (part 1): overview of biomass. Bioresour. Technol.83,37–46 (2003).
  • Bridgwater AV. Catalysis in thermal biomass conversion. Appl. Catal. A Gen.116,5–47 (1994).
  • Devi L, Ptasinki KJ, Janssen FJJG. A review of the primary measures for tar elimination in biomass gasification processes. Biomass Bioenerg.24,125–140 (2003).
  • Tasaka K, Furusawa T, Tsutsumi A. Biomass gasification in fluidized bed reactor with Co catalyst. Chem. Eng. Sci.62,5558–563 (2007).
  • Li J, Xiao B, Yan R, Xu X. Development of a supported tri-metallic catalyst and evaluation of the catalytic activity in biomass steam gasification. Bioresour. Technol.100,5295–5300 (2009).
  • Hanamura K, Kameya Y. Hydrogen-rich gasification of biomass using porous catalyst. Greenhouse Gas Control Technol.7,2579–2582 (2005).
  • Michel R, Rapagna S, Marcello MD et al. Catalytic steam gasification of Miscanthus X giganteus in fluidized bed reactor on olivine based catalysts. Fuel Process. Technol.92,1169–1177 (2011).
  • Gilbert P, Ryu C, Sharifi V, Swithenbank J. Tar reduction in pyrolysis vapours from biomass over a hot char bed. Bioresour. Technol.100,6045–6051 (2009).
  • Ateş F, Işikdağ MA. Evaluation of the role of the pyrolysis temperature in straw biomass samples and characterization of the oils by GC/MS. Energ. Fuel22,1936–1943 (2008).
  • Zhang Y, Kajitani S, Ashizawa M, Oki Y. Tar destruction and coke formation during rapid pyrolysis and gasification of biomass in a drop-tube furnace. Fuel89,302–309 (2010).
  • Delgado J, Aznar MP, Corella J. Biomass gasification with steam in fluidized bed: effectiveness of CaO, MgO, and CaO-MgO for raw gas cleaning. Ind. Eng. Chem. Res.36,1535–1543 (1997).
  • Simell PA, Hakala N, Haario HE. Catalytic decomposition of gasification gas tar with benzene as the model compound. Ind. Eng. Chem. Res.36,42–51 (1997).
  • Swierczynski D, Courson C, Bedel L et al. Characterization of Ni-Fe/MgO/olivine catalyst for fluidized bed steam gasification of biomass. Chem. Mater.18,4025–4032 (2006).
  • Yung MM, Jablonski WS, Magrini-Bair KA. Review of catalytic conditioning of biomass-derived syngas. Energ. Fuel23,1874–1887 (2009).
  • Trimm DL. Coke formation and minimisation during steam reactions. Catal. Today37,233–238 (1997).
  • El-Rub ZA, Bramer EA, Brem G. Review of catalysts for tar elimination in biomass gasification processes. Ind. End. Chem. Res.43,6911–6919 (2004).
  • Srinakruang J, Sato K, Vitidsant T et al. A highly efficient catalyst for tar gasification with steam. Catal. Commun.6,437–440 (2005).
  • Darvell LI, Heiskanen K, Jones JM, Ross AB, Simell P, Williams A. An investigation of alumina-supported catalysts for the selective catalytic oxidation of ammonia in biomass gasification. Catal. Today81,681–692 (2003).
  • Miyazawa T, Kimura T, Nishikawa J, Kado S, Kunimori K, Tomishige K. Catalytic performance of supported Ni catalysts in partial oxidation and steam reforming of tar derived from the pyrolysis of wood biomass. Catal. Today115,254–262 (2006).
  • Pompeo F, Nichio NN, Ferretti OA, Resasco D. Study of Ni catalysts on different supports to obtain systhesis gas. Int. J. Hydrogen Energ.30,1399–1405 (2005).
  • Wen G, Xu Y, Ma H, Xu Z, Tian Z. Production of hydrogen by aqueous-phase reforming of glycerol. Int. J. Hydrogen Energ.33,6657–6666 (2008).
  • Simell PA, Hepola JO, Krause AO. Effects of gasification gas components on tar and ammonia decomposition over hot gas clean up catalysts. Fuel76,1117–1127 (1997).
  • Kong M, Fei J, Wang S, Lu W, Zheng X. Influence of supports on catalytic behavior of nickel catalysts in carbon dioxide reforming of toluene as a model compound of tar from biomass gasification. Bioresour. Technol.102,2004–2008 (2011).
  • Davidian T, Guilhaume N, Iojoiu E, Provendier H, Mirodatos C. Hydrogen production from crude pyrolysis oil by a sequential catalytic process. Appl. Catal. B Environ.73,116–127 (2007).
  • Clause O, Gazzano M, Trifiro F, Vaccari A, Zatorski L. Preparation and thermal reactivity of nickel/chromium and nickel/aluminium hydrotalcite-type precursors. Appl. Catal.73,217–236 (1991).
  • Clause O, Rebours B, Merlen E, Trifiro F, Vaccari A. Preparation and characterization of nickel-aluminum mixed oxides obtained by thermal decomposition of hydrotalcite-type precursors. J. Catal.133,231–246 (1992).
  • Garcia L, Salvador ML, Arauzo J, Bilbao R. Catalytic steam gasification of pine sawdust. Effect of catalyst weight/biomass flow rate and steam/biomass ratios on gas production and composition. Energ. Fuel13,851–859 (1999).
  • Garcia L, Salvador ML, Bilbao R, Arauzo J. Influence of calcination and reduction conditions on the catalyst performance in the pyrolysis process of biomass. Energ. Fuel12,139–143 (1998).
  • Wu C, Williams PT. Hydrogen production by steam gasification of polypropylene with various nickel catalysts. Appl. Catal. B Environ.87,152–161(2009).
  • Bimbela F, Oliva M, Ruiz J, Garcia L, Arauzo J. Catalytic steam reforming of model compounds of biomass pyrolysis liquids in fixed bed: acetol and n-butanol. J. Anal. Appl. Pyrolysis85,204–213 (2009).
  • Bimbela F, Oliva M, Ruiz J, Garcia L, Arauzo J. Hydrogen production by catalytic steam reforming of acetic acid, a model compound of biomass pyrolysis liquids. J. Anal. Appl. Pyrolysis79,112–120 (2007).
  • Arauzo J, Radlein D, Piskorz J, Scott DS. A new catalyst for the catalytic gasification of biomass. Energ. Fuel8,1192–1196 (1994).
  • Medrano JA, Oliva M, Ruiz J, Garcia L, Arauzo J. Catalytic steam reforming of model compounds of biomass pyrolysis liquids in fluidised bed reactor with modified Ni/Al catalysts. J. Anal. Appl. Pyrolysis85,214–225 (2009).
  • Ramos MC, Navascues AI, Garcia L, Bilbao R. Hydrogen production by catalytic steam reforming of acetol, a model compound of bio-oil. Ind. Eng. Chem. Res.46,2399–2406 (2008).
  • Galdamez JR, Garcia L, Bilbao R. Hydrogen production by steam reforming of bio-oil using coprecipitated Ni-Al catalysts. Acetic acid as a model compound. Energ. Fuel19,1133–1142 (2005).
  • Arauzo J, Radlein D, Piskorz J, Scott DS. Catalytic pyrogasification of biomass. Evaluation of modified nickel catalyst. Ind. Eng. Chem. Res.36,67–75 (1997).
  • Choudhary VR, Uphade BS, Mamman AS. Oxidative conversion of methane to syngas over nickel supported on commercial low surface area porous catalyst carriers precoated with alkaline and rare earth oxides. J. Catal.172,281–293(1997).
  • Martinez R, Romero E, Garcia L, Bilbao R. The effect of lanthanum on Ni-Al catalyst for catalytic steam gasification of pine sawdust. Fuel Process. Technol.85,201–214 (2003).
  • Bangala DN, Abatzoglou N, Chornet E. Steam reforming of naphthalene on Ni-Cr/Al2O3 catalysts doped with MgO, TiO2, and La2O3. AlChE J.44,927–936 (1998).
  • Garcia L, French R, Czernik S, Chornet E. Catalytic steam reforming of bio-oils for the production of hydrogen: effects of catalyst composition. Appl. Catal. A Gen.201,225–239 (2000).
  • Furusawa T, Tsutsumi A. Development of cobalt catalysts for the steam reforming of naphthalene as a model compound of tar derived from biomass gasification. Appl. Catal. A Gen.278,195–205(2005).
  • Bona S, Guillen P, Alcalde JG, Garcia L, Bilbao R. Toluene steam reforming using coprecipitated Ni/Al catalysts modified with lanthanum or cobalt. Chem. Eng. J.137,587–597 (2008).
  • Garcia L, Benedicto A, Romeo E, Salvador ML, Arauzo J, Bilbao R. Hydrogen production by steam gasification of biomass using Ni-Al coprecipitated catalysts promoted with magnesium. Energ. Fuel16,1222–1230 (2002).
  • Minowa T, Ogi T. Hydrogen production from cellulose using a reduced nickel catalyst. Catal. Today.45,411–416 (1998).
  • Furusawa T, Tsutsumi A. Comparison of Co/MgO and Ni/MgO catalysts for the steam reforming of naphthalene as a model compound of tar derived from biomass gasification. Appl. Catal. A Gen.278,207–212 (2005).
  • Rapagna S, Jad N, Foscolo PU. Catalytic gasification of biomass to produce hydrogen rich gas. Int. J. Hydrogen Energ.23,551–557 (1998).
  • Sato K, Fujimoto K. Development of new nickel based catalyst for tar reforming with superior resistance to sulfur poisoning and coking in biomass gasification. Catal. Commun.8,1697–1701 (2007).
  • Freni S, Cavallaro S, Mondello N, Spadaro L, Frusteri F. Production of hydrogen for MC fuel cell by steam reforming of ethanol over MgO supported Ni and Co catalysts. Catal. Commun.4,259–268(2003).
  • Furusawa T, Sato T, Sugito H et al. Hydrogen production from the gasification of lignin with nickel catalysts in supercritical water. Int. J. Hydrogen Energ.32,699–704 (2007).
  • Sato T, Furusawa T, Ishiyama Y et al. Effect of water density on the gasification of lignin with magnesium oxide supported nickel catalysts in supercritical water. Ind. Eng. Chem. Res.45,615–622 (2006).
  • Sato T, Sekiguchi G, Saisu M, Watanabe M, Adschiri T, Arai K. Dealkylation and rearrangement kinetics of 2-isopropylphenol in supercritical water. Ind. Eng. Chem. Res.41,3124–3130(2002).
  • Sato T, Haryu E, Adschiri T, Arai K. Noncatalytic recovery of phenol through decomposition of 2-isopropylphenol in supercritical water. Chem. Eng. Sci.59,1247–1253 (2004).
  • Wu C, Williams PT. Effects of gasification temperature and catalyst ratio on hydrogen production from catalytic steam pyrolysis–gasification of polypropylene. Energ. Fuel22,4125–4132 (2008).
  • Williams PT, Brindle AJ. Aromatic chemicals from the catalytic pyrolysis of scrap tyres. J. Anal. Appl. Pyrolysis67,143–164 (2003).
  • Furusawa T, Sato T, Saito M et al. The evaluation of the stability of Ni/MgO catalysts for the gasification of lignin in supercritical water. Appl. Catal. A Gen.327,300–310 (2007).
  • Trimm DL. Catalysis for the control of coking during steam reforming. Catal. Today49,3–10 (1999).
  • Bartholomew CH. Mechanisms of catalyst deactivation. Appl. Catal. A212,17–60 (2001).
  • Frusteri F, Freni S, Chiodo V, Donato S, Bonura G, Cavallaro S. Steam and auto-thermal reforming of bio-ethanol over MgO and CeO2 Ni supported catalysts. Int. J. Hydrogen Energ.31,2193–2199 (2006).
  • Wang S, Lu GQ. Role of CeO2 in Ni/CeO2-Al2O3 catalysts for carbon dioxide reforming of methane. Appl. Catal. B Environ.19,267–277 (1998).
  • Inaba M, Murata K, Saito M et al. Hydrogen production by gasification of cellulose over Ni catalysts supported on zeolite. Energ. Fuel20,432–438 (2006).
  • Adhikari S, Fernando SD, To SDF, Bricka R, Steele PH, Haryanto A. Conversion of Glycerol to hydrogen via a steam reforming process over nickel catalysts. Energ. Fuel22,1220–1226 (2008).
  • Cai X, Dong X, Lin W. Effect of CeO2 on the catalytic performance of Ni/Al2O3 for autothermal reforming of methane. J. Nat. Gas Chem.17,98–102 (2008).
  • Buffoni IN, Pompeo F, Santori GF, Nichio NN. Nickel catalysts applied in steam reforming of glycerol for hydrogen production. Catal. Commun.10,1656–1660 (2009).
  • Profeti LPR, Ticianelli EA, Assaf EM. Production of hydrogen via steam reforming of biofuels on Ni/CeO2-Al2O3 catalysts promoted by noble metals. Int. J. Hydrogen Energ.34,5049–5060 (2009).
  • Haryanto A, Fernando S, Adhikari S. Ultrahigh temperature water gas shift catalysts to increase hydrogen yield from biomass gasification. Catal. Today129,269–274 (2007).
  • Lu Y, Li S, Guo L, Zhang X. Hydrogen production by biomass gasification in supercritical water over Ni/γAl2O3 and Ni/CeO2-γAl2O3 catalysts. Int. J. Hydrogen Energ.35,7161–7168 (2010).
  • Tomishige K, Kimura T, Nishikawa J et al. Promoting effect of the interaction between Ni and CeO2 on steam gasification of biomass. Catal. Commun.8,1074–1079 (2007).
  • Nishikawa J, Miyazawa T, Nakamura K, Asadullah M, Kunimori K, Tomishige K. Promoting effect of Pt addition to Ni/CeO2/Al2O3 catalyst for steam gasification of biomass. Catal. Commun.9,195–201(2008).
  • Kimura T, Miyazawa T, Nishikawa J et al. Development of Ni catalysts for tar removal by steam gasification of biomass. Appl. Catal. B Environ.68,160–170 (2006).
  • Nishikawa J, Nakamura K, Asadullah M, Miyazawa T, Kunimori K, Tomishige K. Catalytic performance of Ni/CeO2/Al2O3 modified with noble metals in steam gasification of biomass. Catal. Today131,146–155(2008).
  • Resini C, Delgado MCH, Presto S et al. Yttria-stabilized zirconia (YSZ) supported Ni-Co alloys (precursor of SOFC anodes) as catalysts for steam reforming of ethanol. Int. J. Hydrogen Energ.33,3728–3735 (2008).
  • Youn MH, Seo JG, Kim P, Kim JJ, Lee HI, Song IK. Hydrogen production by auto-thermal reforming of ethanol over Ni/γ-Al2O3 catalysts: effect of second metal addition. J. Power Sources162,1270–1274 (2006).
  • Youn MP, Seo JG, Kim P, Song IK. Role and effect of molybdenum on the performance of Ni-Mo/ γ-Al2O3 catalysts in the hydrogen production by auto-thermal reforming of ethanol. J. Mol. Catal. A261,276–281(2007).
  • Profeti LPR, Dias JAC, Assaf JM, Assaf EM. Hydrogen production by steam reforming of ethanol over Ni-based catalysts promoted with noble metals. J. Power Sources190,525–533(2009).
  • Nakamura K, Miyazawa T, Sakurai T et al. Promoting effect of MgO addition to Pt/Ni/CeO2/Al2O3 in the steam gasification of biomass. Appl. Catal. B Environ.86,36–44 (2009).
  • Rapagna S, Jand N, Kiennemann A et al. Steam-gasification of biomass in a fluidized-bed of olivine particles. Biomass Bioenerg.19,187–197 (2000).
  • Devi L, Ptasinski KJ, Janssen FJJG. Pretreated olivine as tar removal catalyst for biomass gasifiers: investigation using naphthalene as model biomass tar. Fuel Process. Technol.86,617–737 (2005).
  • Corella J, Toledo JM, Padilla R. Olivene or dolomite as in-bed additive in biomass gasification with air in a fluidized bed: which is better? Energ. Fuel18,713–720 (2004).
  • Swierczynski D, Libs S, Courson C et al. Steam reforming of tar from a biomass gasification process over Ni/olivine catalyst using toluene as a model compound. Appl. Catal. B Environ.74,211–222 (2007).
  • Yang X, Xu S, Xu H, Liu X, Liu C. Nickel supported on modified olivine catalysts for steam reforming of biomass gasification tar. Catal. Commun.11,383–386 (2010).
  • Zhao Z, Lakshminarayanan N, Kuhn JN et al. Optimization of thermally impregnated Ni-olivine catalysts for tar removal. Appl. Catal. A Gen.363,64–72 (2009).
  • Simell PA, Hirvensalo EK, Smolander VT Krause AOI. Biomass gasification with air in a fluidized bed: effect of the in-bed use of dolomite under different operatin conditions. Ind. Eng. Chem. Res.38,4226–4235 (1999).
  • Swaan HM, Kroll VCH, Martin GA, Mirodatos C. Deactivation of supported nickel catalysts during the reforming of methane by carbon dioxide. Catal. Today21,571–578 (1994).
  • Olivares A, Aznar MP, Caballero MA et al. Biomass gasification: produced gas upgrading by in-bed use of dolomite. Industrial and engineering chemistry in-bed use of dolomite. Ind. Eng. Chem. Res.36,5220–5226 (1997).
  • Perez P, Aznar PM, Caballero MA, Gil J, Martin JA, Corella J. Hot gas cleaning and upgrading with a calcined dolomite located downstream a biomass fluidized bed gasifier operating with steam–oxygen mixtures. Energ. Fuel11,1194–1203 (1997).
  • Xu G, Xu S, Li S, Xiao C, Liu S. Steam gasification of apricot stones with olivine and dolomite as down stream catalysts. Fuel Process. Technol.87,375–382 (2006).
  • Wang TJ, Chang J, Wu CZ, Fu Y, Chen Y. The steam reforming of naphthalene over a nickel-dolomite cracking catalyst. Biomass Bioenerg.28,508–514 (2005).
  • Wang TJ, Chang J, Lv P. Zhu J. Novel catalyst for cracking of biomass tar. Energ. Fuel19,22–27 (2005).
  • Felice LD, Courson C, Jand N, Gallucci K, Foscolo PU, Kiennemann A. Catalytic biomass gasification: simultaneous hydrocarbons steam reforming and CO2 capture in a fluidized bed reactor. Chem. Eng. J.154,375–383. (2009).
  • Corujo A, Yerman L, Arizaga B, Brusoni M, Castiglioni J. Improved yield parameters in catalytic steam gasification of forestry residue; optimizing biomass feed rate and catalyst type. Biomass Bioenerg.34,1695–1702 (2010).
  • Srinakruang J, Sato K, Vitidsant T et al. Highly efficient sulphur and coking resistance catalysts for tar gasification with steam. Fuel85,2419–2426 (2006).
  • Hall WJ, Zakaria N, Williams PT. Pyrolysis of latex gloves in the presence of Y-zeolite. Waste Manage.29,797–803 (2009).
  • Hall WJ, Williams PT. Removal of organobromine compounds from the pyrolysis oils of flame retarded plastics using zeolite catalysts. J. Anal. Appl. Pyrolysis81,139–147 (2008).
  • Shen B, Wu C. Pyrolysis of waste typres with zeolite USY and ZSM-5 catalysts. Appl. Catal. B Environ.73,150–157 (2007).
  • Chang JS, Park SE, Chon H. Catalytic activity and coke resistance in the carbon dioxide reforming of methane to synthesis gas over zeolite-supported Ni catalysts. Appl. Catal. A Gen.145,111–124 (1996).
  • Buchireddy PR, Bricka RM, Rodriguez JR, Holmes W. Biomass gasification: catalytic removal of tars over zeolites and nickel supported zeolites. Energ. Fuel24,2707–2715 (2010).
  • Chica A, Savas S. Effective and stable bioethanol steam reforming catalyst based on Ni and Co supported on all-silica delaminated ITQ-2 zeolite. Catal. Today146,37–43 (2009).
  • Luengnaruemitchai A, Kaengsilalai A. Activity of different zeolite-supported Ni catalysts for methane reforming with carbon dioxide. Chem. Eng. J.144,96–102 (2008).
  • Wu C, Williams PT. Investigation of coke formation on Ni-Mg-Al catalyst for hydrogen production from the catalytic steam pyrolysis–gasification of polypropylene. Appl. Catal. B Environ.96,198–207 (2010).
  • Wu C, Williams PT. Investigation of Ni-Al, Ni-Mg-Al and Ni-Cu-Al catalyst for hydrogen production from pyrolysis–gasification of polypropylene. Appl. Catal. B Environ.90,147–156 (2009).
  • Penkova A, Bobadilla L, Ivanova S et al. Hydrogen production by methanol steam reforming on NiSn/MgO-Al2O3 catalysts: the role of MgO addition. Appl. Catal. A Gen.29,184–191, (2011).
  • Aznar MP, Caballero MA, Gil J et al. Commercial steam reforming catalysts to improve biomass gasification with steam-oxygen mixtures. 2. Catalytic tar removal. Ind. Eng. Chem. Res.37,2668–2680 (1998).
  • Caballero MA, Corella J, Aznar MP, Gil J. Biomass gasification with air in fluidized bed. Hot gas cleanup with selected commercial and full-size nickel-based catalysts. Ind. Eng. Chem. Res.39,1143–1154 (2000).
  • Czernik S, French R, Feik C, Chornet E. Hydrogen by catalytic steam reforming of liquid byproducts from biomass thermoconversion process. Ind. Eng. Chem. Res.41,4209–4215 (2002).
  • Roy C, Pakdel H, Zhang HG. Characterization and catalytic gasification of the aqueous by-product from vacuum pyrolysis of biomass. Can. J. Chem. Eng.72,98–105 (1994).
  • Wang D, Czernik S, Montane D, Mann M, Chornet E. Biomass to hydrogen via fast pyrolysis and catalytic steam reforming of the pyrolysis oil or its fractions. Ind. Eng. Chem. Res.36,1507–1518 (1997).
  • Corella J, Orio A, Toledo JM. Biomass gasification with air in a fluidized bed: Exhaustive tar elimination with commercial steam reforming catalysts. Energ. Fuel13,702–709 (1999).
  • Wang D, Czernik S, Chornet E. Production of hydrogen from biomass by catalytic steam reforming of fast pyrolysis oils. Energ. Fuel12,19–24 (1998).
  • Park HJ, Park SH, Sohn JM, Jeon JK, Kim SS, Park YK. Steam reforming of biomass gasification tar using benzene as a model compound over various Ni supported metal oxide catalysts. Bioresour. Technol.101,S101–S103 (2010).
  • Li C, Hirabayashi D, Suzuki K. A crucial role of O2- and O22- on mayenite structure for biomass tar steam reforming over Ni/Ca12Al14O33. Appl. Catal. B Environ.88,351–360 (2009).
  • Sharma A, Nakagawa H, Miura K. Uniform dispersion of Ni nano particles in a carbon based catalyst for increasing catalytic activity for CH4 and H2 production by hydrothermal gasification. Fuel85,2396–2401(2006).
  • Sharma A, Saito I, Nakagawa H, Miura K. Effect of carbonization temperature on the nickel crystallite size of a Ni/C catalyst for catalytic hydrothermal gasification of organic compounds. Fuel86,915–920 (2007).
  • Engelen K, Zhang Y, Draelants DJ, Baron GV. A novel catalytic filter for tar removal from biomass gasification gas: improvement of the catalytic activity in presence of H2S. Chem. Eng. Sci.58,665–670 (2003).

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