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以Cu(Ac)_(2)-Zn(Ac)_(2)溶液为水相的W/O微液滴尺度的有效调控

Controllable regulation of microdroplets size in W/O microemulsion with Cu(Ac)_(2)-Zn(Ac)_(2) solution as aqueous phase
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摘要 微乳液常被用来制备纳米材料,而对微液滴尺寸的有效调控对于纳米材料制备至关重要。本文研究了在Triton X-100微乳液体系中,以Cu(Ac)_(2)-Zn(Ac)_(2)电解质水溶液为水相时,微液滴尺度的变化情况。实验结果表明:在4~12nm的范围内,可以通过改变微乳液中水含量和电解质溶液种类来调节液滴的大小。在一定范围内,无论是水体系还是电解质溶液体系中,微液滴的平均粒径都随着水含量的增加而增大。电解质溶液中金属离子与水分子之间的作用力不同,导致微液滴的粒径分布呈现出不同的变化。需要注意的是,电解质的加入对于微乳液的外观和稳定性没有影响。在以链状烷烃作为油相形成的Cu(Ac)_(2)-Zn(Ac)_(2)电解质微乳液体系中,微液滴的粒径分布更加均匀。最后,本文采用所述的微乳液方法成功制备了CuO-ZnO纳米颗粒。本研究结果对于实现微乳液液滴尺度的可控调节和纳米材料的制备具有重要意义。 Microemulsions are commonly used for the preparation of nanomaterials.The controllable regulation of the size of microdroplets is crucial to the preparation of nanomaterials.When Cu(Ac)_(2)-Zn(Ac)_(2) electrolyte aqueous solution was used as the aqueous phase,the variations of microdroplets sizes of W/O microemulsion system of Triton X-100 were studied systematically.The experimental results showed that the droplet size could be regulated in the range of 4—12nm by changing the water content in the microemulsion and the type of electrolyte solution.And within a certain range,the average size of microdroplets increased with the increase of water content in the system.The different forces between metal ions and water molecules in the electrolyte solution also led to different changes in the particle size distribution of the droplets.The addition of electrolyte did not change the appearance and stability of the microemulsion.In the microemulsion systems with chain alkanes as oil phase,the size distribution of microdroplets with Cu(Ac)_(2)-Zn(Ac)_(2) electrolyte aqueous solution as water phase was more uniform.CuO-ZnO nanoparticles were successfully prepared by the proposed microemulsion method.The results were useful to provide a guide for the controllable regulation of microdroplet size and the preparation of nanomaterials.
作者 李浩然 王岩 张涛 吕莉 唐文翔 唐盛伟 LI Haoran;WANG Yan;ZHANG Tao;LYU Li;TANG Wenxiang;TANG Shengwei(School of Chemical Engineering,Sichuan University,Chengdu 610065,Sichuan,China)
出处 《化工进展》 EI CAS CSCD 北大核心 2024年第9期5168-5176,共9页 Chemical Industry and Engineering Progress
基金 国家自然科学基金(22078203) 中央高校基本科研业务费项目(2022SCUH0041)。
关键词 表面活性剂 电解质 微乳液 微液滴 surfactants electrolytes microemulsion microdroplet
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