纳米粒子在生物燃料应用中的研究进展
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摘要
聚焦于纳米粒子在生物燃料中的应用,重点介绍了纳米粒子在生物氢、生物柴油、生物乙醇和沼气中的研究进展,讨论了影响纳米粒子应用性能的相关因素,提出了目前纳米粒子在生物燃料应用中面临的问题并展望了其应用前景。
This review focuses on the application of nanoparticles in biofuels and introduces emphatically the research progress on applications of nanoparticles in bio-hydrogen,biodiesel,bioethanol and biogas.The factors that affect the application performance of nanoparticles are discussed. Finally,the problems faced by nanoparticles in biofuel applications are presented and their application prospects are given.
This review focuses on the application of nanoparticles in biofuels and introduces emphatically the research progress on applications of nanoparticles in bio-hydrogen,biodiesel,bioethanol and biogas.The factors that affect the application performance of nanoparticles are discussed. Finally,the problems faced by nanoparticles in biofuel applications are presented and their application prospects are given.
引文
[1]Ghimire A,Kumar G,Sivagurunathan P,et al. Bio-hythane production from microalgae biomass:Key challenges and potential opportunities for algal bio-refineries[J]. Bioresour Technol,2017,241:525-536.
[2]Ghimire A,Frunzo L,Pirozzi F,et al.A review on dark fermentative biohydrogen production from organic biomass:Process parameters and use of by-products[J].Applied Energy,2015,144:73-95.
[3]Contreras J E,Rodriguez E A,Taha-Tijerinac J.Nanotechnology applications for electrical transformers-A review[J].Electr Power Syst Res,2017,143:573-584.
[4]Skeffington A,Scheffel A.Exploiting algal mineralization for nanotechnology:Bringing coccoliths to the fore[J]. Curr Opin Biotechnol,2018,49:57-63.
[5]Kucharska K,Glinka M,Rybarczyk P,et al. Hydrogen production from biomass using dark fermentation[J]. Renewable Sustainable Energy Rev,2018,91:665-694.
[6]Ali A,Mahar R,Soomro R,et al.Fe3O4nanoparticles facilitated anaerobic digestion of organic fraction of municipal solid waste for enhancement of methane production[J]. Energy Sources:Part A Recover Util Environ Eff,2017,39:1815-1822.
[7]Pandey A,Gupta K,Pandey A.Effect of nanosized Ti O2on photofermentation by Rhodobacter sphaeroides NMBL-02[J]. Biomass Bioenergy,2015,72:273-279.
[8]Hakamizadeh M,Afshar S,Tadjarodi A,et al. Improving hydrogen production via water splitting over Pt/Ti O2/activated carbon nanocomposite[J].Int J Hydrogen Energy,2014,32:7262-7269.
[9]Leonzio G.Upgrading of biogas to bio-methane with chemical absorption process:Simulation and environmental impact[J]. J Clean Prod,2016,131:364-375.
[10]Su L,Shi X,Guo G,et al.Stabilization of sewage sludge in the presence of nanoscale zero-valent iron(n ZVI):Abatement of odor and improvement of biogas production[J]. J Mater Cycles Waste Manage,2013,15:461-468.
[11]Han Y,Yan W.Reductive dechlorination of trichloroethene by zerovalent iron nanoparticles:Reactivity enhancement through sulfidation treatment[J]. Environ Sci Technol,2016,50:12992-3001.
[12]Koenig J,Boparai H,Lee M,et al. Particles and enzymes:Combining nanoscale zero valent iron and organochlorine respiring bacteria for the detoxification of chloroethane mixtures[J].J Hazard Mater,2016,308:106-112.
[13]Chen Y,Liu T,He H,et al.Fe3O4/ZnMg(Al)O magnetic nanoparticles for efficient biodiesel production[J].Appl Organomet Chem,2018,32:1-10.
[14]Jeon H,Park S,Ahn B,et al.Enhancement of biodiesel production in Chlorella vulgaris cultivation using silica nanoparticles[J]. Biotechnol Bioprocess Eng,2017,22:136-141.
[15]Hebbar H,Math M,Yatish K.Optimization and kinetic study of CaO nano-particles catalyzed biodiesel production from Bombax ceiba oil[J].Energy,2018,143:25-34.
[16]Bet-Moushoul E,Farhadi K,Mansourpanah Y,et al.Application of CaO-based/Au nanoparticles as heterogeneous nanocatalysts in biodiesel production[J].Fuel,2016,164:119-127.
[17]Kim K,Lee O,Lee E. Nano-immobilized biocatalysts for biodiesel production from renewable and sustainable resources[J].Catalysts,2018,8:68-80.
[18]Cherian E,Dharmendirakumar M,Baskar G.Immobilization of cellulase onto MnO2nanoparticles for bioethanol production by enhanced hydrolysis of agricultural waste[J].Chin J Catal,2015,36:1223-1229.
[19]Sekoai P,Daramola M.Effect of metal ions on dark fermentative biohydrogen production using suspended and immobilized cells of mixed bacteria[J].Chem Eng Commun,2018,205:1011-1022.
[20]Santos V,Cruz C.Ethanol and Levan production by sequential bath using Zymomonas mobilis immobilized on alginate and chitosan beads[J].Acta Sci Technol,2016,38:263-271.
[2]Ghimire A,Frunzo L,Pirozzi F,et al.A review on dark fermentative biohydrogen production from organic biomass:Process parameters and use of by-products[J].Applied Energy,2015,144:73-95.
[3]Contreras J E,Rodriguez E A,Taha-Tijerinac J.Nanotechnology applications for electrical transformers-A review[J].Electr Power Syst Res,2017,143:573-584.
[4]Skeffington A,Scheffel A.Exploiting algal mineralization for nanotechnology:Bringing coccoliths to the fore[J]. Curr Opin Biotechnol,2018,49:57-63.
[5]Kucharska K,Glinka M,Rybarczyk P,et al. Hydrogen production from biomass using dark fermentation[J]. Renewable Sustainable Energy Rev,2018,91:665-694.
[6]Ali A,Mahar R,Soomro R,et al.Fe3O4nanoparticles facilitated anaerobic digestion of organic fraction of municipal solid waste for enhancement of methane production[J]. Energy Sources:Part A Recover Util Environ Eff,2017,39:1815-1822.
[7]Pandey A,Gupta K,Pandey A.Effect of nanosized Ti O2on photofermentation by Rhodobacter sphaeroides NMBL-02[J]. Biomass Bioenergy,2015,72:273-279.
[8]Hakamizadeh M,Afshar S,Tadjarodi A,et al. Improving hydrogen production via water splitting over Pt/Ti O2/activated carbon nanocomposite[J].Int J Hydrogen Energy,2014,32:7262-7269.
[9]Leonzio G.Upgrading of biogas to bio-methane with chemical absorption process:Simulation and environmental impact[J]. J Clean Prod,2016,131:364-375.
[10]Su L,Shi X,Guo G,et al.Stabilization of sewage sludge in the presence of nanoscale zero-valent iron(n ZVI):Abatement of odor and improvement of biogas production[J]. J Mater Cycles Waste Manage,2013,15:461-468.
[11]Han Y,Yan W.Reductive dechlorination of trichloroethene by zerovalent iron nanoparticles:Reactivity enhancement through sulfidation treatment[J]. Environ Sci Technol,2016,50:12992-3001.
[12]Koenig J,Boparai H,Lee M,et al. Particles and enzymes:Combining nanoscale zero valent iron and organochlorine respiring bacteria for the detoxification of chloroethane mixtures[J].J Hazard Mater,2016,308:106-112.
[13]Chen Y,Liu T,He H,et al.Fe3O4/ZnMg(Al)O magnetic nanoparticles for efficient biodiesel production[J].Appl Organomet Chem,2018,32:1-10.
[14]Jeon H,Park S,Ahn B,et al.Enhancement of biodiesel production in Chlorella vulgaris cultivation using silica nanoparticles[J]. Biotechnol Bioprocess Eng,2017,22:136-141.
[15]Hebbar H,Math M,Yatish K.Optimization and kinetic study of CaO nano-particles catalyzed biodiesel production from Bombax ceiba oil[J].Energy,2018,143:25-34.
[16]Bet-Moushoul E,Farhadi K,Mansourpanah Y,et al.Application of CaO-based/Au nanoparticles as heterogeneous nanocatalysts in biodiesel production[J].Fuel,2016,164:119-127.
[17]Kim K,Lee O,Lee E. Nano-immobilized biocatalysts for biodiesel production from renewable and sustainable resources[J].Catalysts,2018,8:68-80.
[18]Cherian E,Dharmendirakumar M,Baskar G.Immobilization of cellulase onto MnO2nanoparticles for bioethanol production by enhanced hydrolysis of agricultural waste[J].Chin J Catal,2015,36:1223-1229.
[19]Sekoai P,Daramola M.Effect of metal ions on dark fermentative biohydrogen production using suspended and immobilized cells of mixed bacteria[J].Chem Eng Commun,2018,205:1011-1022.
[20]Santos V,Cruz C.Ethanol and Levan production by sequential bath using Zymomonas mobilis immobilized on alginate and chitosan beads[J].Acta Sci Technol,2016,38:263-271.