科技导报
科技導報
과기도보
SCIENCE & TECHNOLOGY REVIEW
2010年
6期
112-115
,共4页
朱遂一%霍明昕%张蕾蕾%于琪%王天竹
硃遂一%霍明昕%張蕾蕾%于琪%王天竹
주수일%곽명흔%장뢰뢰%우기%왕천죽
氟掺杂%纳米二氧化钛%光催化活性%晶相结构
氟摻雜%納米二氧化鈦%光催化活性%晶相結構
불참잡%납미이양화태%광최화활성%정상결구
fluorine doping%nanometer titanium dioxide%photocatalysis activity%crystal phase structure
氟离子掺杂能够改变TiO_2的光生载流子传输、比表面积、孔道结构、表面酸度等本征性质,从而影响光生电子-空穴派对的复合和对母体化合物的吸附,因此氟离子掺杂能够显著提高TiO_2的光催化活性.尤其是紫外光下的光催化活性.氟掺杂纳米TiO_2在制备过程中,容易受到制备技术、热处理温度、前躯体种类和化学计量等的影响,而使纳米TiO_2的晶体结构和表面性质发生变化,这些变化主要体现在如金红石相形成、生成Ti~(3+)、量子产率增加以及改变吸附性(如表面极性)等方面.本文综述了氟修饰TiO_2的制备及光活性,主要包括催化剂制备方法、相变过程和母体化合物的矿化.
氟離子摻雜能夠改變TiO_2的光生載流子傳輸、比錶麵積、孔道結構、錶麵痠度等本徵性質,從而影響光生電子-空穴派對的複閤和對母體化閤物的吸附,因此氟離子摻雜能夠顯著提高TiO_2的光催化活性.尤其是紫外光下的光催化活性.氟摻雜納米TiO_2在製備過程中,容易受到製備技術、熱處理溫度、前軀體種類和化學計量等的影響,而使納米TiO_2的晶體結構和錶麵性質髮生變化,這些變化主要體現在如金紅石相形成、生成Ti~(3+)、量子產率增加以及改變吸附性(如錶麵極性)等方麵.本文綜述瞭氟脩飾TiO_2的製備及光活性,主要包括催化劑製備方法、相變過程和母體化閤物的礦化.
불리자참잡능구개변TiO_2적광생재류자전수、비표면적、공도결구、표면산도등본정성질,종이영향광생전자-공혈파대적복합화대모체화합물적흡부,인차불리자참잡능구현저제고TiO_2적광최화활성.우기시자외광하적광최화활성.불참잡납미TiO_2재제비과정중,용역수도제비기술、열처리온도、전구체충류화화학계량등적영향,이사납미TiO_2적정체결구화표면성질발생변화,저사변화주요체현재여금홍석상형성、생성Ti~(3+)、양자산솔증가이급개변흡부성(여표면겁성)등방면.본문종술료불수식TiO_2적제비급광활성,주요포괄최화제제비방법、상변과정화모체화합물적광화.
The intrinsic properties of titanium dioxide could be modified by fluorine doping into crystal lattice, including the photocurrent charge carrier immigration property, the specific surface area, the channel structure, the surface acidity, and others. These changes could influence the recombination of photoinduced electron-hole pairs and the absorption of the parent compound, and thus greatly improve the photocatalysis activity of titanium dioxide, especiallly, under irradiation of ultraviolet light. Although fluorine doping of titanium dioxide was prepared in the laboratory scale, some factors may influence the nano-particle's crystal structure and surface properties, such as the preparation method, the annealing temperature, the precursors, the stoichiometric equivalent, etc. Under these influences, the nanometer photocatalyzer may show different photocatalysis activities, which would be embodied in the futile phase transformation, the formation of Ti3+, the increase of quantum yield, the change of absorbability (such as surface polarity), and so forth. Thus the photocatalysis efficiency depends strongly on the methods of fluorine doping , the dosage level and the light source. This paper presents a general review of prepgration and photocatalysis activity of fluorine doped titanium dioxide with respect to catalyst preparation; phase transformation process and the mineralization of parent compounds.