Influence of anode area and electrode gap on the morphology of TiO 2 nanotubes arrays

Journal of Nanomaterials

Volumn 2013, Issue , 2013, Pages

  Wang, Min ^a,b   Jia, Li ^a   Deng, Shuangmei ^b  

^a BEIJING JIAOTONG UNIVERSITY   (China)

^b BEIJING UNIVERSITY OF CIVIL ENGINEERING AND ARCHITECTURE   (China)

Author keywords

[No Author keywords available]

Indexed keywords

ANODE AREA; ANODIZATIONS; ELECTRODE GAP; FIELD EMISSION SCANNING ELECTRON MICROSCOPY; NANOTUBE ARRAYS; NANOTUBES ARRAYS; PHOTO CATALYTIC DEGRADATION; TOTAL VOLATILE ORGANIC COMPOUNDS;

ANODIC OXIDATION; FIELD EMISSION MICROSCOPES; MORPHOLOGY; OXIDES; PHOTODEGRADATION; TITANIUM DIOXIDE; VOLATILE ORGANIC COMPOUNDS;

NANOTUBES;

EID: 84879369438     PISSN: 16874110     EISSN: 16874129     Source Type: Journal    
DOI: 10.1155/2013/534042     Document Type: Article

References (54)

1. 2 photocatalysis: new materials and recent applications. Electrochimica Acta 2012 84 103 111
2. 2 nanotube arrays for environmental pollutants removal. Journal of Hazardous Materials 2011 186 2-3 1374 1383 2-s2.0-79751537370 10.1016/j.jhazmat.2010.12.022
3. Bai J., Liu Y., Li J., Zhou B., Zheng Q., Cai W., A novel thin-layer photoelectrocatalytic (PEC) reactor with double-faced titania nanotube arrays electrode for effective degradation of tetracycline. Applied Catalysis B 2010 98 3-4 154 160 2-s2.0-77954624574 10.1016/j.apcatb.2010.05.024
4. 2 nanotube arrays. Chemosphere 2011 82 1 43 47 2-s2.0-78650194785 10.1016/j.chemosphere.2010.10.013
5. 2 nanotube array by the molecular iron oxide surface modification. Applied Catalysis B 2012 119-120 74 80
6. 2 nanotubes. Applied Surface Science 2012 258 18 7188 7194
7. 2 nanotube arrays prepared by anodization and their photocatalytic activity. Ceramics International 2012 38 7 5791 5797
8. 2 nanotube layers as highly efficient photocatalysts. Small 2007 3 2 300 304 2-s2.0-33847076867 10.1002/smll.200600426
9. 2 nanotubes in mixed organic-inorganic electrolytes and their photoelectrochemical performance. Electrochimica Acta 2009 54 26 6536 6542 2-s2.0-69249133397 10.1016/j.electacta.2009.06.029
10. Kasuga T., Hiramatsu M., Hoson A., Sekino T., Niihara K., Titania nanotubes prepared by chemical processing. Advanced Materials 1999 11 15 1307 1311
11. Chen Q., Zhou W., Du G. H., Peng L. M., Trititanate nanotubes made via a single alkali treatment. Advanced Materials 2002 14 17 1208 1211
12. Tsai C. C., Teng H., Regulation of the physical characteristics of titania nanotube aggregates synthesized from hydrothermal treatment. Chemistry of Materials 2004 16 22 4352 4358 2-s2.0-7044263145 10.1021/cm049643u
13. 2 nanorods with nanotubes as the precursor. Journal of Physical Chemistry B 2006 110 9 4193 4198 2-s2.0-33645657622 10.1021/jp0567321
14. Hoyer P., Formation of a titanium dioxide nanotube array. Langmuir 1996 12 6 1411 1413 2-s2.0-0000364624
15. 2 one-dimensional nanostructured arrays using a one-step templating solution approach. Journal of Physical Chemistry B 2005 109 27 13056 13059 2-s2.0-22944437388 10.1021/jp052203l
16. Zwilling V., Darque-Ceretti E., Boutry-Forveille A., David D., Perrin M. Y., Aucouturier M., Structure and physicochemistry of anodic oxide films on titanium and TA6V alloy. Surface and Interface Analysis 1999 27 7 629 637 2-s2.0-0000811689
17. Gong D., Grimes C. A., Varghese O. K., Hu W., Singh R. S., Chen Z., Dickey E. C., Titanium oxide nanotube arrays prepared by anodic oxidation. Journal of Materials Research 2001 16 12 3331 3334 2-s2.0-0035739786
18. Varghese O. K., Gong D., Paulose M., Grimes C. A., Dickey E. C., Crystallization and high-temperature structural stability of titanium oxide nanotube arrays. Journal of Materials Research 2003 18 1 156 165 2-s2.0-0037820387
19. Varghese O. K., Paulose M., Shankar K., Mor G. K., Grimes C. A., Water-photolysis properties of micron-length highly-ordered titania nanotube-arrays. Journal of Nanoscience and Nanotechnology 2005 5 7 1158 1165 2-s2.0-23744481705 10.1166/jnn.2005.195
20. 2 nanotube arrays. Superlattices and Microstructures 2011 50 1 26 39 2-s2.0-79958825280 10.1016/j.spmi.2011.04.006
21. 2 nanotube arrays obtained by electrochemical oxidation. International Journal of Hydrogen Energy 2011 36 15 8894 8901 2-s2.0-79958810987 10.1016/j.ijhydene.2011. 04.105
22. 2 nanotubes by anodization of Ti thin films for VOC sensing. Thin Solid Films 2011 520 3 953 958
23. 2 nanotube array by periodic anodization of titanium. Electrochemistry Communications 2012 23 68 71
24. 2 nanotube arrays by complete anodization of Ti thin films. Physics Procedia 2012 32 714 718
25. 2 nanotube arrays with ultrahigh aspect ratio via electrochemical anodization. Chemistry of Materials 2008 20 4 1257 1261 2-s2.0-40549145591 10.1021/cm7028917
26. 2 nanotube powders. Journal of Solid State Chemistry 2011 184 3 624 632 2-s2.0-79952453086 10.1016/j.jssc.2011.01.020
27. 2 nanotube arrays and their stabilities as photo(electro) catalysts. Applied Surface Science 2012 258 8 3647 3651
28. 2 nanotubes on titanium substrate. Acta Biomaterialia 2007 3 3 359 367 2-s2.0-34147170044 10.1016/j.actbio.2006.08.004
29. Ou H. H., Lo S. L., Review of titania nanotubes synthesized via the hydrothermal treatment: fabrication, modification, and application. Separation and Purification Technology 2007 58 1 179 191 2-s2.0-35349020093 10.1016/j.seppur.2007.07.017
30. 2 by using carbon nanotubes for the treatment of azo dye. Applied Catalysis B 2005 61 1-2 1 11 2-s2.0-22144498348 10.1016/j.apcatb.2005.03.008
31. 2 nanotube arrays for hydrogen generation via water splitting. Materials Chemistry and Physics 2011 129 1-2 35 39 2-s2.0-79958829842 10.1016/j.matchemphys.2011.03.081
32. 3+ in organic pollutant degradation and water splitting. Journal of Physics and Chemistry of Solids 2011 72 9 1104 1109 2-s2.0-79960616683 10.1016/j.jpcs.2011.06.016
33. 2 nanotube arrays for enhancing visible light photocatalytic performance. Electrochemistry Communications 2011 13 8 861 864 2-s2.0-79960713601 10.1016/j.elecom.2011.05.022
34. Zang L., Macyk W., Lange C., Maier W. F., Antonius C., Meissner D., Kisch H., Visible-light detoxification and charge generation by transition metal chloride modified titania. Chemistry 2000 6 2 379 384 2-s2.0-0033956206
35. 2-based photocatalysts for UV and visible light gas-phase toluene degradation. Thin Solid Films 2006 495 1-2 272 279 2-s2.0-28044448747 10.1016/j.tsf.2005.08.361
36. 2O under visible irradiation. Journal of Hazardous Materials 2009 168 1 215 219 2-s2.0-67349214348 10.1016/j.jhazmat.2009.02.020
37. 2 composites. Applied Surface Science 2011 257 13 5813 5819 2-s2.0-79952534303 10.1016/j.apsusc.2011.01.110
38. 2 p-n heterojunction network catalyst. Environmental Science and Technology 2010 44 19 7641 7646 2-s2.0-77957361835 10.1021/es101711k
39. 2 nanotubes: self-organized electrochemical formation, properties and applications. Current Opinion in Solid State and Materials Science 2007 11 1-2 3 18 2-s2.0-44449173500 10.1016/j.cossms.2007.08.004
40. 4F electrolyte: roughness, wetting behavior and adhesion for implant applications. Materials Chemistry and Physics 2009 117 2-3 460 464 2-s2.0-67651211462 10.1016/j.matchemphys.2009.06.023
41. 2 nanotube array growth by anodization. Journal of Physical Chemistry C 2007 111 20 7235 7241 2-s2.0-34250349643 10.1021/jp070273h
42. Kim S. E., Lim J. H., Lee S. C., Nam S. C., Kang H. G., Choi J., Anodically nanostructured titanium oxides for implant applications. Electrochimica Acta 2008 53 14 4846 4851 2-s2.0-41049089819 10.1016/j.electacta. 2008.02.005
43. 2 nanotube arrays to 134 m in length. The Journal of Physical Chemistry B 2006 110 33 16179 16184
44. 2 nanotubes in fluoride containing electrolytes. Transactions of Nonferrous Metals Society of China (English Edition) 2009 19 4 842 845 2-s2.0-68549115308 10.1016/S1003-6326(08)60361-1
45. 2 metal membrane. Desalination 2011 279 1-3 359 366
46. 2 nanocolumns. Applied Surface Science 2011 257 19 8177 8181 2-s2.0-79958806111 10.1016/j.apsusc.2011.03.050
47. 2 nanotube arrays on Ti prepared via electrochemical oxidation. Journal of Alloys and Compounds 2011 509 24 L221 L227 2-s2.0-79956227160 10.1016/j.jallcom.2011.03.154
48. 2 nanotubes prepared by anodization method. Energy Procedia 2011 9 435 439
49. 2 nanotube arrays in formamide-water mixtures. Journal of Physical Chemistry C 2007 111 1 21 26 2-s2.0-33847633901 10.1021/jp066352v
50. 2 nanotube arrays (TNTAs): progressive strategies towards visible light responsive photoanode, a review. Energy and Environmental Science 2011 4 4 1065 1086 2-s2.0-79953655655 10.1039/c0ee00488j
51. 2 nanotube array films for enhancement in photocatalytic activity. Solar Energy Materials and Solar Cells 2009 93 10 1875 1880 2-s2.0-68349101985 10.1016/j.solmat.2009. 07.001
52. Mo J., Zhang Y., Xu Q., Lamson J. J., Zhao R., Photocatalytic purification of volatile organic compounds in indoor air: a literature review. Atmospheric Environment 2009 43 14 2229 2246 2-s2.0-63149152654 10.1016/j.atmosenv.2009.01.034
53. Lockman Z., Sreekantan S., Ismail S., Schmidt-Mende L., MacManus-Driscoll J. L., Influence of anodisation voltage on the dimension of titania nanotubes. Journal of Alloys and Compounds 2010 503 2 359 364 2-s2.0-77956672546 10.1016/j.jallcom.2009.12.093
54. Oh H. J., Kim I. K., Jang K. W., Lee J. H., Lee S., Chi C. S., Influence of electrolyte and anodic potentials on morphology of titania nanotubes. Metals and Materials International 2012 18 4 673 677