通过水热法制得磷修饰氧化钛,它在亚甲基蓝和对氯苯酚的降解以及消除大肠杆菌的实验中都表现出高于纯氧化钛的优异活性,甚至优于商品化催化剂P25.在捕获剂中降解亚甲基蓝的实验证实羟基自由基是最主要的活性氧物种,并且磷修饰氧化钛在光照下拥有较强的产生羟基自由基的能力,同时,磷修饰氧化钛具有非常高的热稳定性,直到950℃才会发生从锐钛矿到金红石的相变,这是因为粒子表面的磷酸根阻止了金红石在界面的成核因而抑制了相变发生.磷修饰氧化钛的这种优异性质使得它即使在900℃焙烧后也能有效地降解水中污染物.
The phosphorous-modified TiO2 (P-TiO2) was synthesized by a hydrothermal method.The as-prepared P-TiO2 was evaluated for the degradation of methylene blue,the dechlorination of 4-chlorophenol,and the inactivation of Escherichia coli.In all these experiments,P-TiO2 shows superior activity compared with pure TiO2 and even better activity than the commercially available P25 in most cases.By carrying out methylene blue degradation in the presence of different scavengers,·OH radicals were found to be the dominant reactive oxidizing species.The excellent performance of P-TiO2 was correlated with its pronounced ability to generate ·OH radicals under illumination.We also found that P-TiO2 is extraordinarily stable against annealing.Its transformation from anatase to mtile does not occur until calcination as high as 950 ℃.This phase transformation is retarded since the phosphate species on the surface of the particles acts as a barrier to grain boundary nucleation.This peculiar feature of P-TiO2 gives it reliable performance during water decontamination even after calcination at 900 ℃ since it retains a 100% anatase phase at this stage.
参考文献
| [1] | Legrini O;Oliveros E;Brauna A M .[J].Chemical Reviews,1993,93:671. |
| [2] | Hoffmann M R;Martin S T;Choi W;Bahnemann D W .[J].Chemical Reviews,1995,95:69. |
| [3] | Andreozzi A R;Caprio V;Insola A;Marotta R .[J].Catalysis Today,1999,53:51. |
| [4] | Linsebigler A L;Lu G;Yates J T .[J].Chemical Reviews,1995,95:735. |
| [5] | Lawless D;Serpone N;Meisel D .[J].Journal of Physical Chemistry,1991,95:5166. |
| [6] | Cho M;Chung H;Choi W;Yoon J .[J].Water Research,2004,38:1069. |
| [7] | Gandhe, AR;Naik, SP;Fernandes, JB .Selective synthesis of N-doped mesoporous TiO2 phases having enhanced photocatalytic activity[J].Microporous and Mesoporous Materials,2005(2):103-109. |
| [8] | Kumar K N P;Keizer K;Burggraaf A J;Okubo T Nagamoto H Morooka S .[J].Nature,1992,358:48. |
| [9] | Shannon R D;Pask J A .[J].Journal of the American Ceramic Society,1965,48:391. |
| [10] | Gouma P I;Dutta P K;Mills M J .[J].Nano Mat,1999,11:1231. |
| [11] | Machida M;Norimoto K;Kimura T .[J].Journal of the American Ceramic Society,2005,88:95. |
| [12] | Hirano M;Ota K;Iwata H .[J].Chemistry of Materials,2004,16:3725. |
| [13] | Periyat P;Pillai S C;Mccormack D E;Colreavy J Hinder S J .[J].Journal of Physical Chemistry C,2008,112:7644. |
| [14] | Choi H;Kim YJ;Varma RS;Dionysiou DD .Thermally stable nanocrystalline TiO2 photocatalysts synthesized via sol-gel methods modified with ionic liquid and surfactant molecules[J].Chemistry of Materials: A Publication of the American Chemistry Society,2006(22):5377-5384. |
| [15] | Colon G;Hidalgo MC;Munuera G;Ferino I;Cutrufello MG;Navio JA .Structural and surface approach to the enhanced photocatalytic activity of sulfated TiO2 photocatalyst[J].Applied Catalysis, B. Environmental: An International Journal Devoted to Catalytic Science and Its Applications,2006(1/2):45-59. |
| [16] | 卢晗锋,周瑛,徐柏庆,陈银飞,刘化章.超临界乙醇干燥法制备高热稳定性Fe-TiO2[J].分子催化,2008(01):54-60. |
| [17] | Li HX;Zhang XY;Huo YN;Zhu J .Supercritical preparation of a highly active S-doped TiO2 photocatalyst for methylene blue mineralization[J].Environmental Science & Technology: ES&T,2007(12):4410-4414. |
| [18] | 张敬畅,高玲玲,曹维良.纳米TiO2-SiO2复合光催化剂的超临界流体干燥法制备及其光催化性能研究[J].无机化学学报,2003(09):934-940. |
| [19] | 陈艳敏,钟晶,陈锋,张金龙.氟掺杂纳米TiO_2薄膜的低温制备及其光催化性能[J].催化学报,2010(01):120-125. |
| [20] | 魏凤玉,桑蕾.高光催化活性和易分离回收的硫掺杂 TiO2纳米管[J].催化学报,2009(04):335-339. |
| [21] | 郑华荣,崔言娟,张金水,丁正新,王心晨.Pt助剂对N掺杂TiO2可见光光催化性能的影响[J].催化学报,2011(01):100-105. |
| [22] | Zhao D;Chen C C;Wang Y F;Ji H W Ma W H Zang L Zhao J C .[J].Journal of Physical Chemistry C,2008,112:5993. |
| [23] | Yu JC.;Zhang LZ.;Zheng Z.;Zhao JC. .Synthesis and characterization of phosphated mesoporous titanium dioxide with high photocatalytic activity[J].Chemistry of Materials,2003(11):2280-2286. |
| [24] | Korosi L;Papp S;Bertoti I;Dekany I .[J].Chemistry of Materials,2007,19:4811. |
| [25] | Li F F;Jiang Y S;Xia M S;Sun M M Xue B Liu D R Zhang X G .[J].Journal of Physical Chemistry C,2009,113:18134. |
| [26] | Zheng R Y;Lin L;Xie J L;Zhu Y X Xie Y C .[J].Journal of Physical Chemistry C,2008,112:15502. |
| [27] | Yang, HG;Liu, G;Qiao, SZ;Sun, CH;Jin, YG;Smith, SC;Zou, J;Cheng, HM;Lu, GQ .Solvothermal Synthesis and Photoreactivity of Anatase TiO2 Nanosheets with Dominant {001} Facets[J].Journal of the American Chemical Society,2009(11):4078-4083. |
| [28] | Jin C;Zheng R Y;Guo Y;Xie J L Zhu Y X Xie Y C .[J].Journal of Molecular Catalysis A:Chemical,2009,313:44. |
| [29] | Korosi L;Oszko A;Galbacs G;Richardt A;Zollmer V;Dekany I .Structural properties and photocatalytic behaviour of phosphate-modified nanocrystalline titania films[J].Applied Catalysis, B. Environmental: An International Journal Devoted to Catalytic Science and Its Applications,2007(1/2):175-183. |
| [30] | Zhang HZ.;Banfield JF. .Thermodynamic analysis of phase stability of nanocrystalline titania[J].Journal of Materials Chemistry: An Interdisciplinary Journal dealing with Synthesis, Structures, Properties and Applications of Materials, Particulary Those Associated with Advanced Technology,1998(9):2073-2076. |
| [31] | Reidy D J;Holmes J D;Morris M A .[J].Journal of the European Ceramic Society,2006,26:1527. |
| [32] | Zhang J;Li M J;Feng Z C;Chen J Li C .[J].Journal of Physical Chemistry B,2005,110:927. |
| [33] | Mendive C B;Bahnemann D W;Blesa M A .[J].Catalysis Today,2005,101:237. |
| [34] | Joo J;Kwon S G;Yu T;Cho M Lee J Yoon J Hyeon T .[J].Journal of Physical Chemistry B,2005,109:15297. |
| [35] | Irmak S;Kusvuran E;Erbatur O .Degradation of 4-chloro-2-methylphenol in aqueous solution by UV irradiation in the presence of titanium dioxide[J].Applied Catalysis, B. Environmental: An International Journal Devoted to Catalytic Science and Its Applications,2004(2):85-91. |
- 下载量()
- 访问量()
- 您的评分:
-
10%
-
20%
-
30%
-
40%
-
50%