1) reverse-coprecipitation
反向化学共沉淀
1.
The PrxCe1-xO2-δ nano oxides were synthesized by the reverse-coprecipitation method, loaded on MWCNT.
通过反向化学共沉淀法制备了PrxCe1-xO2-δ稀土纳米复合氧化物作为助催化掺杂剂,将其包覆在多壁碳纳米管(MWCNTs)的表面作为催化剂复合载体,然后使用了柠檬酸盐-KBH4液相还原法制备了粒径分布均匀、性质稳定的Pt纳米溶胶,并沉积在上述载体中得到负载型Pt-PrxCe1-xO2-δ/CNT复合电催化剂,制备的催化剂中Pt载量为20%(质量分数)。
2) chemical precipitating method
反向化学沉淀法
3) reverse coprecipitation
反向共沉淀
1.
Preparation of Y_2O_3-ZrO_2 ceramic powders by reverse coprecipitation;
反向共沉淀法制备Y_2O_3-ZrO_2陶瓷粉末
4) inverse titrating chemical co-precipitation
反滴定化学共沉淀
1.
MgFe_2O_4 composite oxide nano-powder of spinel-type was prepared by inverse titrating chemical co-precipitation method, and its microstructure was characterized by means of powder XRD and TEM.
用反滴定化学共沉淀法制备了纳米尺寸尖晶石型的复合金属氧化物MgFe_2O_4粉体。
5) chemical co-precipitation
化学共沉淀
1.
Study of La-doped nanosized SnO_2 by chemical co-precipitation;
化学共沉淀法制备镧掺杂纳米二氧化锡的研究
2.
W-Ni-Fe composite oxides nano-powder has been prepared from finely grained tungstate synthesized by chemical co-precipitation and oxided at 600℃.
以化学共沉淀法制备的盐在600℃下氧化,可得W-Ni-Fe复合氧化物,检测分析显示W-Ni-Fe复合氧化物粉的晶粒直径XRD-d为36 nm,W-Ni-Fe复合氧化物粉的颗粒粒径BET-d为98 nm;从SEM图分析看出该复合氧化物粉颗粒团聚性低,压坯EDXS的表面电子图像和元素面分布图显示该复合氧化物粉中W、Ni、Fe元素分布状态是高度均匀分布。
3.
In this work,nanometer magnetite(Fe_3O_4) particles were prepared by chemical co-precipitation,NH_3·H_2O was chosen as precipitating agent,and was added to the mixed aqueous solution containing ferric and ferrous ions to produce nanometer Fe_3O_4 particles.
采用化学共沉淀法制备纳米磁性Fe3O4粒子。
6) chemical coprecipitation
化学共沉淀
1.
Antimony-doped tin oxide (ATO) nanorods with rutile structure were successfully prepared by annealing nanoscale precursor powders at 1 000~1 100(°C) for 1~3 h, which were produced by chemical coprecipitation using SnCl_4·5H_2O and SbCl_3.
以SnCl4·5H2O和SbCl3为原料,采用化学共沉淀法制得纳米级掺锑二氧化锡(ATO)的前驱物,经1000~1100°C焙烧1~3h,成功制备了直径为10~40nm,长为60~500nm的金红石结构的ATO纳米棒。
2.
A series of (Sr1-xPbx) TiO3 ceramic powders were prepared through chemical coprecipitation process.
采用化学共沉淀法制备了一系列(Sr1-xPbx)TiO3陶瓷粉体,通过差热-热重(DTA-TG)分析确定了共沉淀产物的煅烧温度。
3.
71μm to prepare the W-Cu composite by using chemical coprecipitation.
以H2WO4和CuSO4·H2O(W:Cu=70g:30g)为原料,采用化学共沉淀方法制备W-Cu化合物粉末,其反应条件为:反应温度25℃±1℃,pH值5。
补充资料:化学沉淀剂
化学沉淀剂
chemical precipitation agent
huoxue ehend旧nJ-化学沉淀剂(ch。二ical prec三pitat沁n agent) 能使废水中的溶解态污染物(分子或离子)转化为不溶态而沉淀析出的化学物质。常用的化学沉淀剂有氢氧化物(如NaOH、Ca(OH)2)、碳酸盐(如Na:CO3、Ca-CO3、MgCO3)、硫化物(NaZS、HZS、CaS)、卤化物(NaCI),有机的淀粉黄原酸醋亦有使用的。用化学沉淀法处理的污染物主要为重金属离子(Ag+、HgZ+、CdZ十、PbZ+、Zn之+、Cr3一、Cu“+、Fe“十、NiZ+等)、碱土金属离子(C aZ十、BaZ十等)及某些非金属(砷、氟、硫、硼)。作为反应产物的氢氧化物(如Cu(OH)2、C:(OH)3、Fe(()H):等)、碳酸盐(如BaCO3、CdC()3等)、硫化物(如HgZS、HgS、AgZS等)及卤化物(仅有AgCI及CaFZ)等,因其溶度积很小而沉淀析出。应用化学沉淀法时,要准确控制溶液的pH值。 (周开君)
说明:补充资料仅用于学习参考,请勿用于其它任何用途。
参考词条