中国有色金属学报
中國有色金屬學報
중국유색금속학보
THE CHINESE JOURNAL OF NONFERROUS METALS
2009年
11期
2038-2043
,共6页
魏智强%汪宝珍%闫晓燕%朱林%杨晓红%闫鹏勋
魏智彊%汪寶珍%閆曉燕%硃林%楊曉紅%閆鵬勛
위지강%왕보진%염효연%주림%양효홍%염붕훈
NiO包覆%纳米颗粒%核-壳结构%钝化%氧化特性
NiO包覆%納米顆粒%覈-殼結構%鈍化%氧化特性
NiO포복%납미과립%핵-각결구%둔화%양화특성
NiO encapsulated%nanoparticles%core-shell structure%passivation%oxidization resistance
采用直流电弧等离子体技术制备NiO包覆Ni纳米颗粒,对初产物经过钝化处理得到有氧化膜保护的NiO包覆Ni纳米颗粒.采用高分辨透射电子显微镜(HRTEM)、X射线衍射(XRD)、透射电子显微镜(TEM)、选区电子衍射(SAED)、热重和差示扫描量热分析仪(TGA/DSC)以及傅里叶变换红外光谱 (FTIR)等手段对试样的成分、表面组成、形貌、晶体结构、粒度、红外吸收性能和氧化特性进行了分析.结果表明:经过表面钝化处理的NiO包覆Ni纳米颗粒具有明显的核-壳结构,内核为纳米Ni,外壳为NiO氧化物;颗粒呈球形,粒度均匀,分散性良好,粒径分布在20~70 nm范围,平均粒径为44 nm,壳层氧化膜的厚度为5~8 nm;壳核结构可防止纳米Ni颗粒的进一步氧化和团聚,且使红外吸收峰发生蓝移.
採用直流電弧等離子體技術製備NiO包覆Ni納米顆粒,對初產物經過鈍化處理得到有氧化膜保護的NiO包覆Ni納米顆粒.採用高分辨透射電子顯微鏡(HRTEM)、X射線衍射(XRD)、透射電子顯微鏡(TEM)、選區電子衍射(SAED)、熱重和差示掃描量熱分析儀(TGA/DSC)以及傅裏葉變換紅外光譜 (FTIR)等手段對試樣的成分、錶麵組成、形貌、晶體結構、粒度、紅外吸收性能和氧化特性進行瞭分析.結果錶明:經過錶麵鈍化處理的NiO包覆Ni納米顆粒具有明顯的覈-殼結構,內覈為納米Ni,外殼為NiO氧化物;顆粒呈毬形,粒度均勻,分散性良好,粒徑分佈在20~70 nm範圍,平均粒徑為44 nm,殼層氧化膜的厚度為5~8 nm;殼覈結構可防止納米Ni顆粒的進一步氧化和糰聚,且使紅外吸收峰髮生藍移.
채용직류전호등리자체기술제비NiO포복Ni납미과립,대초산물경과둔화처리득도유양화막보호적NiO포복Ni납미과립.채용고분변투사전자현미경(HRTEM)、X사선연사(XRD)、투사전자현미경(TEM)、선구전자연사(SAED)、열중화차시소묘량열분석의(TGA/DSC)이급부리협변환홍외광보 (FTIR)등수단대시양적성분、표면조성、형모、정체결구、립도、홍외흡수성능화양화특성진행료분석.결과표명:경과표면둔화처리적NiO포복Ni납미과립구유명현적핵-각결구,내핵위납미Ni,외각위NiO양화물;과립정구형,립도균균,분산성량호,립경분포재20~70 nm범위,평균립경위44 nm,각층양화막적후도위5~8 nm;각핵결구가방지납미Ni과립적진일보양화화단취,차사홍외흡수봉발생람이.
The NiO encapsulated Ni nanoparticles were prepared by direct current (DC) arc plasma method and subsequently passivation. The chemical composition, morphology, crystal microstructure, particle size, infrared spectra properties and oxidization resistance of the product were analyzed using the high-resolution transmission electron microscopy (HRTEM), X-ray diffractometry (XRD), transmission electron microscopy (TEM), corresponding selected-area electron diffractometry (SAED), thermogravimetric analyzer (TGA) differential scanning calorimeter (DSC) and Fourier transform infrared spectrum (FTIR). The results show that the NiO encapsulated Ni nanoparticles have clear core-shell structure. The core consists of Ni particles, while the shell consists of NiO. The samples are homogeneously distributed with spherical shape and well dispersed, the particle sizes distribute from 20 to 70 nm with average particle size of about 44 nm, and the thickness of the shell is 5-8 nm. The core-shell structure can prevent Ni nanopartictes from oxidation and agglomeration, and the infrared absorption band show blue-shifts.
