期刊文献+

Electrocatalytic conversion of CO_2 to liquid fuels using nanocarbon-based electrodes 被引量:5

Electrocatalytic conversion of CO_2 to liquid fuels using nanocarbon-based electrodes
下载PDF
导出
摘要 Recent advances on the use of nanocarbon-based electrodes for the electrocatalytic conversion of gaseous streams of CO2 to liquid fuels are discussed in this perspective paper. A novel gas-phase electrocatalytic cell, different from the typical electrochemical systems working in liquid phase, was developed. There are several advantages to work in gas phase, e.g. no need to recover the products from a liquid phase and no problems of CO2 solubility, etc. Operating under these conditions and using electrodes based on metal nanoparticles supported over carbon nanotube (CNT) type materials, long C-chain products (in particular isopropanol under optimized conditions, but also hydrocarbons up to C8-C9) were obtained from the reduction of CO2. Pt-CNT are more stable and give in some cases a higher productivity, but Fe-CNT, particular using N-doped carbon nanotubes, give excellent properties and are preferable to noble-metal-based electrocatalysts for the lower cost. The control of the localization of metal particles at the inner or outer surface of CNT is an importact factor for the product distribution. The nature of the nanocarbon substrate also plays a relevant role in enhancing the productivity and tuning the selectivity towards long C-chain products. The electrodes for the electrocatalytic conversion of CO2 are part of a photoelectrocatalytic (PEC) solar cell concept, aimed to develop knowledge for the new generation artificial leaf-type solar cells which can use sunlight and water to convert CO2 to fuels and chemicals. The CO2 reduction to liquid fuels by solar energy is a good attempt to introduce renewables into the existing energy and chemical infrastructures, having a higher energy density and easier transport/storage than other competing solutions (i.e. H2). Recent advances on the use of nanocarbon-based electrodes for the electrocatalytic conversion of gaseous streams of CO2 to liquid fuels are discussed in this perspective paper. A novel gas-phase electrocatalytic cell, different from the typical electrochemical systems working in liquid phase, was developed. There are several advantages to work in gas phase, e.g. no need to recover the products from a liquid phase and no problems of CO2 solubility, etc. Operating under these conditions and using electrodes based on metal nanoparticles supported over carbon nanotube (CNT) type materials, long C-chain products (in particular isopropanol under optimized conditions, but also hydrocarbons up to C8-C9) were obtained from the reduction of CO2. Pt-CNT are more stable and give in some cases a higher productivity, but Fe-CNT, particular using N-doped carbon nanotubes, give excellent properties and are preferable to noble-metal-based electrocatalysts for the lower cost. The control of the localization of metal particles at the inner or outer surface of CNT is an importact factor for the product distribution. The nature of the nanocarbon substrate also plays a relevant role in enhancing the productivity and tuning the selectivity towards long C-chain products. The electrodes for the electrocatalytic conversion of CO2 are part of a photoelectrocatalytic (PEC) solar cell concept, aimed to develop knowledge for the new generation artificial leaf-type solar cells which can use sunlight and water to convert CO2 to fuels and chemicals. The CO2 reduction to liquid fuels by solar energy is a good attempt to introduce renewables into the existing energy and chemical infrastructures, having a higher energy density and easier transport/storage than other competing solutions (i.e. H2).
出处 《Journal of Energy Chemistry》 SCIE EI CAS CSCD 2013年第2期202-213,共12页 能源化学(英文版)
基金 supported by the Toyota Motor Europe
关键词 CO2 conversion solar fuels CNT Fe nanoparticles NANOCARBON H2 production CO2 conversion solar fuels CNT Fe nanoparticles nanocarbon H2 production
  • 相关文献

参考文献11

  • 1C. Ampelli,Rosalba Passalacqua,Siglinda Perathoner,Gabriele Centi,Dangsheng S. Su,Gisela Weinberg.Synthesis of TiO2 Thin Films: Relationship Between Preparation Conditions and Nanostructure[J].Topics in Catalysis (-).2008(1-4)
  • 2Greg P Smestad,Aldo Steinfeld.Review:photochemicaland thermochemical production of solar fuels from H2Oand CO2 using metal oxide catalysts[].Industrial andEngineering Chemistry Research.2012
  • 3Centi G,Perathoner S.Opportunities and Prospects in the Chemical Recycling of CarbonDioxide to Fuels[].Catalysis Today.2009
  • 4Centi G,Perathoner S. ChemSusChem . 2010
  • 5Roy S C,Varghese O K,Paulose M,Grimes C A. ACS Nano . 2010
  • 6E A Quadrelli,G Centi,J L Duplan,S Perathoner.Carbon Dioxide Recycling: Emerging Large-Scale Technologies with Industrial Potential[].ChemSusChem.2011
  • 7Hoffmann M R,Moss J A,Baum M M. Dalton Transactions . 2011
  • 8G Centi,R Passalacqua,S Perathoner,DS Su,G Weinberg,R Schl?gl. Physical Chemistry Chemical Physics . 2007
  • 9S Perathoner,R Passalacqua,G Centi,DS Su,G Weinberg. Catalysis Today . 2007
  • 10G Centi,S Perathoner,G Winé,M Gangeri. Green Chemistry . 2007

同被引文献14

引证文献5

二级引证文献30

相关作者

内容加载中请稍等...

相关机构

内容加载中请稍等...

相关主题

内容加载中请稍等...

浏览历史

内容加载中请稍等...
;
使用帮助 返回顶部