摘要
采用化学沉淀法制备三元Ag/AgCl-LaCO_3OH纳米棒光催化剂.将Ag/AgCl引入LaCO_3OH(LCO)纳米棒后,可同时实现光吸收范围紫外光区拓展至可见光吸收和光生载流子的高效分离.可见光照射下,金属Ag单质等离子共振(SPR)效应诱导电荷-空穴有效分离,使其热电子传输至LCO样品缺陷能级.随后表面O_2捕获光生电子产生超氧自由基·O_2-,该自由基对氧化NO过程起主导作用.空穴可以迁移至AgCl表面与Cl^-相互作用转化Cl^0,直接参与氧化NO后再还原为Cl^-, Cl^-再与Ag^+结合生成AgCl,有效避免了AgCl的光腐蚀.优化过后的Ag/AgCl-LaCO_3OH纳米棒复合材料的可见光净化NO去除率高达54.0%,远高于纯的LCO(3.1%)和Ag/AgCl(8.0%)的可见光催化性能.利用原位红外光谱实时动态监测Ag/AgCl-LaCO_3OH光催化氧化NO的反应过程,结合自由基捕获结果,从分子层面揭示其反应机理,并提出Ag/AgCl-LaCO_3OH光催化性能增强机制.本研究结果对等离子体基半导体复合材料光催化反应机理及环境净化应用提供新的认识.
Air pollution has become a focused issue worldwide with the rapid development of industry.As one of the major air pollutants,nitric oxide(NO)could cause serious atmospheric problems,such as acid rain,haze and photochemical smog.Photocatalysis as a green technology has received increasing attention,because it has represented greatly potential application over the late decades.As a novel photocatalyst,LaCO3OH possesses relatively negative conduction band and positive valence band edges,which enbles sufficient potential for photocatalytic air decomposition.But the band gap of LaCO3OH(4.1 eV)allows only a small portion of solar spectrum in the ultraviolet(UV)light region to be absorbed.To extend the light absorption spectra into the visible light region,the combination of narrow band gap Ag/AgCl with the wide band gap LaCO3OH to build heterojunction could utilize abundant solar light.Noble metal nanoparticles(NPs)showed strong visible light absorption due to surface Plasmon resonance effect(SPR).In particular,silver NPs show SPR in the visible region,which has been utilized to develop efficient plasmonic photocatalysts.In this study,a three-component Ag/AgCl-LaCO3OH nanorod photocatalyst has been fabricated successfully through a chemical precipitation treatment and applied to photocatalytic NO removal.The as-prepared samples were characterized by XRD,SEM,TEM,XPS,UV-vis DRS,PL and ESR.The photocatalytic NO oxidation process was monitored by in situ DRIFTS.The results indicated that the visible-light harvesting and the photogenerated carrier separation can be enhanced simultaneously,which could result from introduction of Ag/AgCl into LaCO3OH(LCO)nanorod photocatalyst.Under visible-light irradiation,the photogenerated electron-hole pairs separation is promoted by the plasma resonance(SPR)effect of the metallic Ag0.The hot electrons would be transferred to the defect level endowed by the oxygen vacancies of the LCO.Subsequently,the electron can be transferred to the surface of LCO,captured by O2 to form·O2-radicals,which plays a dominant role in the photocatalytic NO oxidation.In addition,the holes would be transferred to the surface of AgCl,and interact with Cl-to transform Cl0,which can directly participate in the oxidation of NO.Furthermore,Cl0 can be reduced to Cl-and react with Ag+to forming AgCl,avoiding the photocorrosion of AgCl effectively.Meanwhile,the effect of the mol ratio of Ag/AgCl on the photocatalytic performance was also evaluated.The optimized Ag/AgCl-LCO(mol ratio at 75%)nanorods demonstrated a high NO removal ratio of 54.0%,which far exceeding that of the individual LCO(3.1%)or Ag/AgCl(18.0%)photocatalyst.Moreover,the in situ FT-IR spectra was used to dynamically monitor the intermediate toxic by-products,in combination with the active species,and further reveal the mechanism of photocatalytic NO oxidation from the molecular level.The reaction mechanism can be described as Ag+visible light→e-+h+,e-+O2→·O2-,h++AgCl→Cl0+Ag+,·O2+NO→NO3-,Cl0+NO→NO3-+Cl-,NO2+·OH→NO2+H2 O,NO2+·OH→NO3-+H+and Cl-+Ag+→AgCl.The present work could provide perspectives for advancing the photocatalysis efficiency,offer a new insight of the photocatalytic reaction mechanism and promote large-scale environmental decontamination applications of plasmabased semiconductor composites.
作者
雷奔
孙明禄
冉茂希
李佳芮
陈鹏
高春凤
张育新
张贤明
董帆
Ben Lei;Minglu Sun;Maoxi Ran;Jiarui Li;Peng Chen;Chunfeng Gao;Yuxin Zhang;Xianming Zhang;Fan Dong(Engineering Research Center for Waste Oil Recovery Technology and Equipment of Ministry of Education,College of Environment and Resources,Chongqing Technology and Business University,Chongqing 400067,China;Research Center for Environmental Science&Technology,Institute of Fundamental and Frontier Sciences,University of Electronic Science and Technology of China,Chengdu 611731,China;College of Materials Science and Engineering,Chongqing University,Chongqing 400044,China)
出处
《科学通报》
EI
CAS
CSCD
北大核心
2019年第14期1485-1494,共10页
Chinese Science Bulletin
基金
国家自然科学基金优秀青年科学基金(21822601)
国家自然科学基金(21777011)
国家万人计划青年拔尖人才计划
国家重点研发计划(2016YFC02047)
环境与能源催化重庆市高校创新团队建设计划(CXTDG201602014)资助
