titanate ceramic including Sr2+ was produced with,self- propagation high-temperation synthesis (SHS )technology.
探索采用燃烧合成(SHS)技术制备包容锶核素(Sr2+)的钛酸盐陶瓷固化体,根据自蔓延高温合成热力学分析,计算钛酸盐固化体的绝热燃烧温度Tad大于临界绝热燃烧温度,说明反应能自发进行并合成致密的CaTiO3固化体。
Transition element substituted titanic acid nanotubes were fabricated by a hydrothermal method using transition elements (Cr, Mn, Fe, Co, Ni, Cu) doped anatase TiO2 nanopowders as precursors.
近年来,以TiO2为原料与浓N aO H反应合成的钛酸纳米管具有比其原料TiO2更大的表面积和孔体积,且对丙烯有光催化氧化降解活性而备受关注[2]。
The Au photocatalyst loaded on titanic acid nanotube was prepared by a chemical method, and the structure and morphology of the catalyst were characterized by means of TEM, XPS, XRD and DRS.
用化学方法制备了负载金的纳米管钛酸(Au/H2Ti2O4(OH)2)光催化剂,并用TEM,XPS,XRD和DRS等技术对催化剂进行了表征。
The nanotubed titanic acid (H 2Ti 2O 4(OH) 2) was synthesized and its morphology and structure were investigated.
在实验室合成了具有较大比表面积和纳米管特性的纳米管钛酸H2 Ti2 O4(OH) 2 ,对其热处理前后的形貌和结构进行了表征 ,将其作为气 固色谱吸附剂制备出一种新型纳米管钛酸石英PLOT柱 ,同时考察了这种纳米管结构的钛酸作为固定相对C1~C4气体烷烃混合物、空气和SF6以及CO和CO2 的分离性能。
Synthesis of titanate nanotubes and the mechanism of their formation;
钛酸和钛酸钠纳米管的制备及形成过程
Nanotubes made from layered H_2Ti_3O_7 trititanate;
层状钛酸(H_2Ti_3O_7)形成的纳米管(英文)