The synthesis of micro and nano WO3 powders under the sparks of plasma electrolytic oxidation of Al in a tungstate electrolyte

被引:28
作者
Zhan, Tingyan [1 ]
Tu, Wenbin [1 ]
Cheng, Yulin [1 ]
Han, Junxiang [1 ]
Su, Bin [1 ]
Cheng, Yingliang [1 ]
机构
[1] Hunan Univ, Coll Mat Sci & Engn, Changsha 410082, Hunan, Peoples R China
来源
CERAMICS INTERNATIONAL | 2018年 / 44卷 / 09期
基金
中国国家自然科学基金;
关键词
Plasma electrolytic oxidation; WO3; Al; Micro and nano sized powders; Sublimation; ORGANIZED POROUS WO3; CU-LI ALLOY; PHOTOCATALYTIC ACTIVITY; ALUMINATE ELECTROLYTES; FORMATION MECHANISM; ALKALINE-SOLUTIONS; METHYLENE-BLUE; NANOPOROUS WO3; ANODIC GROWTH; OXIDE FILMS;
D O I
10.1016/j.ceramint.2018.03.054
中图分类号
TQ174 [陶瓷工业]; TB3 [工程材料学];
学科分类号
0805 ; 080502 ;
摘要
Plasma electrolytic oxidation (PEO) is commonly known as a coating technique. However, the present study shows that PEO of pure Al in 10 g l(-1) Na2WO4 center dot 2H(2)O leads to the synthesis of micro and nano sized powders of WO3. The as-synthesized WO3 powders have been characterized by SEM, TEM and photocatalytic tests. The plasma discharges during the PEO process have been investigated by real-time imaging and spectrographic method. The energetic features of the single discharge at different stages of PEO have been evaluated. It was suggested that the electrolyte species were directly decomposed into tungsten oxides within the discharge channels and then the oxides re-entered the electrolyte due to the lower melting and boiling points of WO3, and more importantly, its tendency of sublimation.
引用
收藏
页码:10402 / 10411
页数:10
相关论文
共 58 条
[21]  
KLAPKIV MD, 1994, MATER SCI+, V30, P333, DOI 10.1007/BF00569685
[22]   Enhanced photoelectrochemical anticorrosion performance of WO3/TiO2 nanotube composite films formed by anodization and electrodeposition [J].
Liang, Yan ;
Guan, Zi-Chao ;
Wang, Hai-Peng ;
Du, Rong-Gui .
ELECTROCHEMISTRY COMMUNICATIONS, 2017, 77 :120-123
[23]   An investigation of the coating/substrate interface of plasma electrolytic oxidation coated aluminum [J].
Liu, Chen ;
He, Donglei ;
Yan, Qin ;
Huang, Zhiquan ;
Liu, Peng ;
Li, Dalong ;
Jiang, Guirong ;
Ma, Haojie ;
Nash, Philip ;
Shen, Dejiu .
SURFACE & COATINGS TECHNOLOGY, 2015, 280 :86-91
[24]   Nanostructure-based WO3 photoanodes for photoelectrochemical water splitting [J].
Liu, Xien ;
Wang, Fengying ;
Wang, Qing .
PHYSICAL CHEMISTRY CHEMICAL PHYSICS, 2012, 14 (22) :7894-7911
[25]   Plasma electrolytic oxide layers as promising systems for catalysis [J].
Lukiyanchuk, I. V. ;
Rudnev, V. S. ;
Tyrina, L. M. .
SURFACE & COATINGS TECHNOLOGY, 2016, 307 :1183-1193
[26]   Anodic-spark oxidation of aluminum alloy in tungstate electrolytes [J].
Lukiyanchuk, IV ;
Rudnev, VS ;
Andenko, NA ;
Kaidalova, TA ;
Panin, ES ;
Gordienko, PS .
RUSSIAN JOURNAL OF APPLIED CHEMISTRY, 2002, 75 (04) :573-578
[27]   Surface morphology, composition and thermal behavior of tungsten-containing anodic spark coatings on aluminium alloy [J].
Lukiyanchuk, IV ;
Rudnev, VS ;
Kuryavyi, VG ;
Boguta, DL ;
Bulanova, SB ;
Gordienko, PS .
THIN SOLID FILMS, 2004, 446 (01) :54-60
[28]   Real-time imaging of coating growth during plasma electrolytic oxidation of titanium [J].
Matykina, E. ;
Berkani, A. ;
Skeldon, P. ;
Thompson, G. E. .
ELECTROCHIMICA ACTA, 2007, 53 (04) :1987-1994
[29]   Diagnostics of an electrolytic microarc process for aluminium alloy oxidation [J].
Mécuson, F ;
Czerwiec, I ;
Belmonte, T ;
Dujardin, L ;
Viola, A ;
Henrion, G .
SURFACE & COATINGS TECHNOLOGY, 2005, 200 (1-4) :804-808
[30]   Preparation of WO3 nanoparticles and application to NO2 sensor [J].
Meng, Dan ;
Yamazaki, Toshinari ;
Shen, Yanbai ;
Liu, Zhifu ;
Kikuta, Toshio .
APPLIED SURFACE SCIENCE, 2009, 256 (04) :1050-1053
123456