高等学校化学学报
高等學校化學學報
고등학교화학학보
CHEMICAL JOURNAL OF CHINESE UNIVERSITIES
2014年
2期
357-361
,共5页
达胡白乙拉%王晓晖%李晓天
達鬍白乙拉%王曉暉%李曉天
체호백을랍%왕효휘%리효천
TiO2 纤维%静电纺丝法%水热法%Fe3O4纳米粒子%光催化%纳米Ag修饰
TiO2 纖維%靜電紡絲法%水熱法%Fe3O4納米粒子%光催化%納米Ag脩飾
TiO2 섬유%정전방사법%수열법%Fe3O4납미입자%광최화%납미Ag수식
TiO2 nanofibers%Electrospinning technique%Hydrothermal method%Fe3 O4 nanoparticles%Photo-catalytic efficiency%Modified with Ag nanoparticles
通过静电纺丝法制备了含有Fe3 O4纳米粒子的TiO2纳米纤维,采用水热法对该纤维表面进行纳米Ag修饰,制备出具有较强磁性和较好光催化性能的复合纤维.采用 X 射线衍射( XRD )、扫描电子显微镜( SEM)、透射电子显微镜( TEM)和紫外-可见光谱( UV-Vis)等对样品的结构和形貌进行表征,并以罗丹明B ( Rh B)水溶液降解为模型反应,考察样品在紫外光照射下的光催化性能.结果表明,所制备的TiO2为锐钛矿结构, Fe3 O4纳米粒子均匀分布在TiO2纤维中, Ag纳米颗粒比较均匀地分散在磁性TiO2纤维表面.经过纳米Ag修饰后,材料的光吸收能力大为增强,吸收带红移并扩展到可见光区.在紫外光照射40 min后,合成样品对Rh B的降解率达到99.5%.此外, Fe3 O4纳米粒子的存在使该材料具有较强的磁性,可通过外加磁场将其分离回收.
通過靜電紡絲法製備瞭含有Fe3 O4納米粒子的TiO2納米纖維,採用水熱法對該纖維錶麵進行納米Ag脩飾,製備齣具有較彊磁性和較好光催化性能的複閤纖維.採用 X 射線衍射( XRD )、掃描電子顯微鏡( SEM)、透射電子顯微鏡( TEM)和紫外-可見光譜( UV-Vis)等對樣品的結構和形貌進行錶徵,併以囉丹明B ( Rh B)水溶液降解為模型反應,攷察樣品在紫外光照射下的光催化性能.結果錶明,所製備的TiO2為銳鈦礦結構, Fe3 O4納米粒子均勻分佈在TiO2纖維中, Ag納米顆粒比較均勻地分散在磁性TiO2纖維錶麵.經過納米Ag脩飾後,材料的光吸收能力大為增彊,吸收帶紅移併擴展到可見光區.在紫外光照射40 min後,閤成樣品對Rh B的降解率達到99.5%.此外, Fe3 O4納米粒子的存在使該材料具有較彊的磁性,可通過外加磁場將其分離迴收.
통과정전방사법제비료함유Fe3 O4납미입자적TiO2납미섬유,채용수열법대해섬유표면진행납미Ag수식,제비출구유교강자성화교호광최화성능적복합섬유.채용 X 사선연사( XRD )、소묘전자현미경( SEM)、투사전자현미경( TEM)화자외-가견광보( UV-Vis)등대양품적결구화형모진행표정,병이라단명B ( Rh B)수용액강해위모형반응,고찰양품재자외광조사하적광최화성능.결과표명,소제비적TiO2위예태광결구, Fe3 O4납미입자균균분포재TiO2섬유중, Ag납미과립비교균균지분산재자성TiO2섬유표면.경과납미Ag수식후,재료적광흡수능력대위증강,흡수대홍이병확전도가견광구.재자외광조사40 min후,합성양품대Rh B적강해솔체도99.5%.차외, Fe3 O4납미입자적존재사해재료구유교강적자성,가통과외가자장장기분리회수.
Fe3 O4/TiO2 nanofibers were prepared via electrospinning technique. Then, the samples were modified with Ag nanoparticles by hydrothermal method to obtain the composite fibers with strong magnetism and excellent photocatalytic efficiency. XRD, SEM, TEM and UV-Vis adsorption spectra were used to charac-terize and analyze the structure and morphology. The photocatalytic efficiency was tested under ultraviolet light irradiation using Rh B degradation as the model reaction. The results showed that TiO2 in all samples were anatases and Ag nanoparticles were scattered on the magnetic TiO2 fiber surface averagely. The UV-Vis spectra showed that TiO2 photoadsoption ability enhanced and the adsorption range were shifted to the visible light region. After modification with Ag nanoparticles, the photocatalytic efficiency of Rh B degradation rate can reach 99. 5% under 40 min UV light irradiation. The new material with strong magnetism can be separated easily and cyclically used by adding the magnetic field.