安庆师范学院学报(自然科学版)
安慶師範學院學報(自然科學版)
안경사범학원학보(자연과학판)
JOURNAL OF ANQING TEACHERS COLLEGE(NATURAL SCIENCE)
2015年
3期
75-81
,共7页
水热法%超重力%纳米材料%ZnS
水熱法%超重力%納米材料%ZnS
수열법%초중력%납미재료%ZnS
hydrothermal method%high gravity%nano materials%ZnS
以ZnCl2和Na2 S2 O3为前驱物在二氯苯/水溶液界面上,在超重力为1000/g的条件下水热合成了高密度的ZnS 纳米陶瓷微球,研究了前驱物浓度、温度和超重力大小对ZnS 纳米陶瓷微球性能的影响。采用FE-SEM,TEM, XRD,FT-IR, UV-Vis和BET对样品的形貌、微结构、物相和性能进行表征。结果发现,ZnS纳米陶瓷微球是由尺寸为2-20 nm的ZnS晶粒组成的直径为300-500 nm的微球,其密度与施加的超重力大小有关。随着超重力的增大,晶粒粒度减小,制得的ZnS纳米陶瓷微球的密度就增大。在120℃,1000/g超重力的条件下,在二氯苯/水溶液界面上反应30 min制备得到的ZnS纳米陶瓷微球具有高分散性和较高的密度。
以ZnCl2和Na2 S2 O3為前驅物在二氯苯/水溶液界麵上,在超重力為1000/g的條件下水熱閤成瞭高密度的ZnS 納米陶瓷微毬,研究瞭前驅物濃度、溫度和超重力大小對ZnS 納米陶瓷微毬性能的影響。採用FE-SEM,TEM, XRD,FT-IR, UV-Vis和BET對樣品的形貌、微結構、物相和性能進行錶徵。結果髮現,ZnS納米陶瓷微毬是由呎吋為2-20 nm的ZnS晶粒組成的直徑為300-500 nm的微毬,其密度與施加的超重力大小有關。隨著超重力的增大,晶粒粒度減小,製得的ZnS納米陶瓷微毬的密度就增大。在120℃,1000/g超重力的條件下,在二氯苯/水溶液界麵上反應30 min製備得到的ZnS納米陶瓷微毬具有高分散性和較高的密度。
이ZnCl2화Na2 S2 O3위전구물재이록분/수용액계면상,재초중력위1000/g적조건하수열합성료고밀도적ZnS 납미도자미구,연구료전구물농도、온도화초중력대소대ZnS 납미도자미구성능적영향。채용FE-SEM,TEM, XRD,FT-IR, UV-Vis화BET대양품적형모、미결구、물상화성능진행표정。결과발현,ZnS납미도자미구시유척촌위2-20 nm적ZnS정립조성적직경위300-500 nm적미구,기밀도여시가적초중력대소유관。수착초중력적증대,정립립도감소,제득적ZnS납미도자미구적밀도취증대。재120℃,1000/g초중력적조건하,재이록분/수용액계면상반응30 min제비득도적ZnS납미도자미구구유고분산성화교고적밀도。
High densified ZnS polycrystalline microspheres have been successfully synthesized by the hydrothermal method with high gravity field using ZnCl2 and Na2 S2 O3 as precursors in the aqueous solution–chlorobenzene system. The effect of precursor concentration, temperature and the relative centrifugal field on the property of ZnS microspheres is investigated. The products are characterized by field-emission scanning electron microscopy (FE-SEM), Transmission electron microscopy (TEM), powder X-ray diffraction ( XRD) , UV-Vis, IR spectra and BET. It is found that the as-prepared products are the spherical ZnS particles with the diameter of 300-500nm, which is self-assembled by the crystallites with the size of 2-20nm. The density of the microsphere is relevant with the relative centrifugal field. The smaller the size of ZnS crystallites is, the bigger the density of the formed ZnS particles is. High densified ZnS polycrystalline microspheres have been successfully synthesized by the hydrothermal method with gravity field of 1000/g at 120 ℃ for 30 min in the aqueous solution–chlorobenzene system.