南昌大学学报(工科版)
南昌大學學報(工科版)
남창대학학보(공과판)
JOURNAL OF NANCHANG UNIVERSITY ENGINEERING & TECHNOLOGY EDITION
2014年
4期
311-316
,共6页
卓明鹏%王怡萍%胡海鸿%李颖毅%胡建东%陈伟凡
卓明鵬%王怡萍%鬍海鴻%李穎毅%鬍建東%陳偉凡
탁명붕%왕이평%호해홍%리영의%호건동%진위범
纳米钕基氧化物%掺杂%乙二醇%溶胶-凝胶法%高氯酸铵%热分解%催化性能
納米釹基氧化物%摻雜%乙二醇%溶膠-凝膠法%高氯痠銨%熱分解%催化性能
납미녀기양화물%참잡%을이순%용효-응효법%고록산안%열분해%최화성능
neodymia-based oxide nanoparticles%doping%ethylene glycol%sol-gel method%ammonium perchlo-rate%thermal decomposition%catalytic property
采用乙二醇溶胶-凝胶法制备氧化钕基氧化物纳米粒子,研究乙二醇与Nd3+的摩尔比、煅烧温度和掺杂对产物结构的影响及其对高氯酸铵热分解的催化性能。研究表明:当乙二醇与Nd3+的摩尔比为10,70℃加热回流2 h,90℃干燥26 h,700℃煅烧2 h,可得到平均粒径为43.6 nm的球形纳米氧化钕;3.4 mol% Mn掺杂Nd2 O3纳米粉体催化高氯酸铵热分解使其在310~350℃和400~470℃的2个小放热峰合并为一个以347.7℃为中心的强放热峰,表观分解热由515 J/g上升到1250 J/g,高于纳米Nd2 O3催化下的1140 J/g,证明了Mn2+掺杂可进一步提高纳米Nd2 O3的催化活性。
採用乙二醇溶膠-凝膠法製備氧化釹基氧化物納米粒子,研究乙二醇與Nd3+的摩爾比、煅燒溫度和摻雜對產物結構的影響及其對高氯痠銨熱分解的催化性能。研究錶明:噹乙二醇與Nd3+的摩爾比為10,70℃加熱迴流2 h,90℃榦燥26 h,700℃煅燒2 h,可得到平均粒徑為43.6 nm的毬形納米氧化釹;3.4 mol% Mn摻雜Nd2 O3納米粉體催化高氯痠銨熱分解使其在310~350℃和400~470℃的2箇小放熱峰閤併為一箇以347.7℃為中心的彊放熱峰,錶觀分解熱由515 J/g上升到1250 J/g,高于納米Nd2 O3催化下的1140 J/g,證明瞭Mn2+摻雜可進一步提高納米Nd2 O3的催化活性。
채용을이순용효-응효법제비양화녀기양화물납미입자,연구을이순여Nd3+적마이비、단소온도화참잡대산물결구적영향급기대고록산안열분해적최화성능。연구표명:당을이순여Nd3+적마이비위10,70℃가열회류2 h,90℃간조26 h,700℃단소2 h,가득도평균립경위43.6 nm적구형납미양화녀;3.4 mol% Mn참잡Nd2 O3납미분체최화고록산안열분해사기재310~350℃화400~470℃적2개소방열봉합병위일개이347.7℃위중심적강방열봉,표관분해열유515 J/g상승도1250 J/g,고우납미Nd2 O3최화하적1140 J/g,증명료Mn2+참잡가진일보제고납미Nd2 O3적최화활성。
Neodymium-based oxide nanoparticles were synthesized via the none-aqueous sol-gel process based on hydrated yttrium nitrate and ethylene glycol. The effects of the molar ratio of ethylene glycol to neodymium ion, calcination temperature and metal ion doping on structure of the products were studied. The catalytic performance of the as-prepared samples for the ammonium perchlorate( AP)decomposition was investigated. The results indicated that the nano-sized neodymia spherical particles with 43 . 6 nm in average particle size could be obtained after 2 h reflux at 70 ℃,26 h drying into xerogel at 90 ℃ followed by 2 h annealing of xerogel and that the addition of the 3 . 4 mol% Mn-doped neodymia nanoparticles into AP incorporates two small exothermic peaks of AP in the temper-ature ranges of 310-350 ℃ and 400-470 ℃ into a strong exothermic peak of AP centered at 347 . 7 ℃,increases the apparent decomposition heat from 515 J/g to 1 250 J/g,higher than that of AP catalyzed by the equal amount of neodymia nanoparticles by 110 J/g. Therefore,the catalytic property of neodymia nanoparticles for AP thermal de-composition can be further enhanced by Mn2+ doping.