期刊文献+

发光二极管用于活性炭负载光催化剂反应器中挥发性有机化合物的降解(英文)

Alternative Use of Light Emitting Diodes in an Activated Charcoal-Supported Photocatalyst Reactor for the Control of Volatile Organic Compounds
下载PDF
导出
摘要 The applicability of ultraviolet-light emitting diodes(LEDs)as a light source for photocatalysis using granular activated charcoal (GAC)impregnated with transition metal-enhanced photocatalysts for the control of volatile organic compounds(VOCs)was investigated. Two target compounds(toluene and methyl mercaptan)were selected to evaluate the removal activities of the TiO2/GAC composites.The photocatalysts were prepared by a sol-gel method.Methyl trimethoxy silane was added as a precursor sol solution to bind the photocatalyst with the GAC.Metal(Zn 2+ ,Fe 3+ ,Ag + ,and Cu 2+ )enhanced TiO2/GAC composites were prepared and tested for their photocatalytic activities under 400 nm LED irradiation.The specific surface area(SSA)and the surface chemical composition of the prepared composites were investigated.The SSAs of all the impregnated composites were similar to those of pure GAC.Both field emission-scanning electron microscopy and energy dispersive spectroscopic analysis confirmed that titanium and the impregnated metals were deposited on the surface of the adsorbent.The breakthrough time for GAC toward toluene or methyl mercaptan gas increased upon photocatalytic impregnation and LED illumination.Using different binders affected the breakthrough time of the TiO2/GAC composite and the addition of zinc oxide to TiO2 increased the VOC removal capacity of the GAC composite. The applicability of ultraviolet-light emitting diodes(LEDs)as a light source for photocatalysis using granular activated charcoal (GAC)impregnated with transition metal-enhanced photocatalysts for the control of volatile organic compounds(VOCs)was investigated. Two target compounds(toluene and methyl mercaptan)were selected to evaluate the removal activities of the TiO2/GAC composites.The photocatalysts were prepared by a sol-gel method.Methyl trimethoxy silane was added as a precursor sol solution to bind the photocatalyst with the GAC.Metal(Zn 2+ ,Fe 3+ ,Ag + ,and Cu 2+ )enhanced TiO2/GAC composites were prepared and tested for their photocatalytic activities under 400 nm LED irradiation.The specific surface area(SSA)and the surface chemical composition of the prepared composites were investigated.The SSAs of all the impregnated composites were similar to those of pure GAC.Both field emission-scanning electron microscopy and energy dispersive spectroscopic analysis confirmed that titanium and the impregnated metals were deposited on the surface of the adsorbent.The breakthrough time for GAC toward toluene or methyl mercaptan gas increased upon photocatalytic impregnation and LED illumination.Using different binders affected the breakthrough time of the TiO2/GAC composite and the addition of zinc oxide to TiO2 increased the VOC removal capacity of the GAC composite.
出处 《催化学报》 SCIE CAS CSCD 北大核心 2011年第5期756-761,共6页
基金 supported by the Korea Institute of Environmental Science and Technology
关键词 granular activated charcoal TITANIA sol-gel method light emitting diode surface chemical composition zinc oxide granular activated charcoal titania sol-gel method light emitting diode surface chemical composition zinc oxide
  • 引文网络
  • 相关文献

参考文献34

  • 1Cetin E, Odabasi M, Seyfioglu R. Sci Total Environ, 2003, 312:103.
  • 2Liu Y, Shao M, Fu L, Lu S, Zheng L, Tang D. Atmos Environ, 2008, 42:6247.
  • 3Roukos J, Riffault V, Locoge N, Plaisance H. Environ Poll, 2009, 157:3001.
  • 4OEHHA (Office of Environmental Health Hazard Assessment) Proposition 65 Status Report Safe Harbor Levels: No Significant Risk Levels for Carcinogens and Maximum Allowable Dose Levels for Chemicals Causing Reproductive Toxicity.California Environmental Protection Agency, OEHHA, Sacramento, CA, 2003.
  • 5Atkinson R, Arey J. Atmos Environ, 2003, 37(suppl. 2): 197.
  • 6Destallats H, Lunden M M, Singer B C, Coleman B K, Dodgson A T, Wesehler C J, Nazaroff W W. Environ Sci Technol, 2006, 40:4421.
  • 7Liu J, Huang Z H, Wang Z S, Kang F Y. dEnvironSci-China, 2004,16:53.
  • 8Giraudet S, Pre P.Tezel H, Le Cloirec E Carbon, 2006, 44: 2413.
  • 9Sasaki T, Matsumoto A, Yamashita Y. Colloid Surf A, 2008, 325:166.
  • 10Yu F D, Luo L G. Grevillot G. Chem Eng Proc, 2007, 46:70.

相关主题

;
使用帮助 返回顶部