The results proved that nano structured Pd doped WO3 film has an excellent gasochromic property.
研究结果表明,纳米掺钯气致变色WO 3薄膜有着良好的气致变色特性。
WO3 catalyst can be reused for 4 times and the isolated yield of adipic acid is still above 70%.
三氧化钨催化剂重复使用4次,己二酸的分离产率仍可达到70%以上。
WO3 precursor solution was prepared by Sol-gel method. The films were printed by dip-coating method.
采用溶胶-凝胶方法制备WO3前驱液,利用浸渍-提拉法使其成膜。
The formation of these WO3 tubes is attributed to the lateral coalescence of tungsten oxide nanowires.
这种氧化钨管是由多根平行生长的氧化钨纳米线横向联合而成。
Photocatalytic degradation of methylene blue dye in aqueous solution with WO3 dispersion has been investigated.
以WO 3粉末为催化剂,研究了在水溶液中次甲基蓝染料的光催化降解。
The mixed powder of WO3 and carbon was in-situ synthesized to get the dense WC bulk by a spark plasma sintering technique.
用放电等离子烧结技术将WO3和炭黑的混合粉原位合成为致密的wc块体。
The WO3 film is prepared by the Spin coating-Pyrolysis method with the amphiphilic block copolymer F127 as the soft template.
采用旋涂-热解工艺,以双亲嵌段共聚物F127为软模板剂,合成出WO3薄膜。
All kinds of characterizations and the research progress for WO3 films were summarized and the prospect of films was reviewed.
概述了WO 3薄膜的各种表征手段和近年来国内外的研究现状等,并对其未来发展趋势进行展望。
Its crystal structures were analyzed by X-ray diffraction (XRD) method. The deposition technology of the WO3 thin film was obtained.
利用X射线衍射(XRD)方法对薄膜的结构进行了分析,得出了WO 3薄膜的沉积工艺。
In this paper, WO3 thin film was deposited on glass substrate and silicon slice by DC reactive magnetron sputtering and using metal tungsten as target.
本文采用直流反应磁控溅射工艺,以金属钨为靶材,在玻璃和单晶硅片上沉积了WO 3薄膜。
Furthermore, the present status of research on character of WO3 thin films is briefly reviewed. Some Suggestions of future developing trend of nanometric WO3 thin films are proposed.
对纳米wo3的性质研究现状作了简要概述,并提出了纳米wo 3薄膜的发展前景。
The WO3 material with interwoven meshwork conformation was successfully prepared using eggshell membrane as template by an aqueous soakage technique followed by calcination treatment.
以鸡蛋壳内膜为模板,通过简单环保的液相浸渍技术结合热处理工艺制备了具有蛋膜分级结构特征的WO3纳米材料。
The diffusion of WO3 is the restrictive step of reduction process of WO3. Improving fluidity of slag and enlarging areas of reaction interface can accelerate reduction process of WO3.
还原WO3的限制性环节是WO3在熔渣中的扩散,改善渣的流动性,扩大反应界面能加快WO3的还原;
The ball-to-powder weight ratio RBP had a significant effect on solid-state reduction reaction between WO3 and graphite. The higher RBP, the shorter is the incubation period of the reduction reaction.
球粉比对WO3和石墨的固态还原反应有显著影响,随球粉比增大,固态反应的诱发时间缩短。
The ball-to-powder weight ratio RBP had a significant effect on solid-state reduction reaction between WO3 and graphite. The higher RBP, the shorter is the incubation period of the reduction reaction.
球粉比对WO3和石墨的固态还原反应有显著影响,随球粉比增大,固态反应的诱发时间缩短。
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