金属<strong>Rb</strong>纳米溶胶的超声乳化制备及点火特性

doi:10.11900/0412.1961.2021.00001

金属学报

2022, Vol. 58

Issue (6): 792-798 DOI: 10.11900/0412.1961.2021.00001

研究论文

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金属Rb纳米溶胶的超声乳化制备及点火特性

郭雨静¹^,², 鲍皓明¹(

), 符浩¹^,², 张洪文¹, 李文宏³, 蔡伟平¹^,²

^1.中国科学院合肥物质科学研究院固体物理研究所合肥 230031
^2.中国科学技术大学研究生院科学岛分院合肥 230026
^3.河北铷铯科技有限公司承德 063000

Ultrasonic Emulsification Preparation of Metallic Rubidium Sol and Its Ignition Performance

GUO Yujing¹^,², BAO Haoming¹(

), FU Hao¹^,², ZHANG Hongwen¹, LI Wenhong³, CAI Weiping¹^,²

^1.Institute of Solid State Physics, Hefei Institutes of Physical Science, Chinese Academy of Sciences, Hefei 230031, China
^2.Graduate School of Science Island, University of Science and Technology of China, Hefei 230026, China
^3.Hebei Rubidium Cesium Technology Co. Ltd., Chengde 063000, China

引用本文:

郭雨静, 鲍皓明, 符浩, 张洪文, 李文宏, 蔡伟平. 金属Rb纳米溶胶的超声乳化制备及点火特性[J]. 金属学报, 2022, 58(6): 792-798.
Yujing GUO, Haoming BAO, Hao FU, Hongwen ZHANG, Wenhong LI, Weiping CAI. Ultrasonic Emulsification Preparation of Metallic Rubidium Sol and Its Ignition Performance[J]. Acta Metall Sin, 2022, 58(6): 792-798.

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摘要:

基于Rb的低熔点特点,提出了固/液转变+超声分散的纳米化策略,即：将熔化的液态Rb置于特定介质(甲苯)中进行超声乳化,进而冷却凝固形成固态纳米颗粒以实现其纳米化。通过这种策略,成功获得了分散在甲苯里的Rb纳米颗粒。这些Rb纳米颗粒呈近球形,平均粒径约为45 nm。金属Rb纳米颗粒的尺寸可通过调节超声功率进行控制。随着超声功率的降低,颗粒的平均粒径增加。当超声功率降至320和240 W时,平均粒径分别增加至55和70 nm。金属Rb纳米颗粒具有良好的点火作用,可实现有机物甲苯在显著低于其着火点的温度下(如120℃)快速引燃(点火时间小于1 s),且随着温度的升高,甲苯的点火时间变短。当温度为250℃时,可在0.25 s内点燃甲苯。本工作不仅为金属Rb的纳米化提供了新的途径,而且还可望为新型含能材料及点火器件的设计提供新思路与依据。

关键词 ： Rb纳米颗粒, 溶胶, 超声乳化, 点火特性

Abstract：

Metallic rubidium (Rb) has great potential in various fields, such as energy, catalysis, and medical treatment. Fragmenting bulk Rb to the nanoscale is essential for its efficient application in these fields. However, as an alkali metal with a high chemical activity, Rb reacts violently with trace water, oxygen, and others; thus, preparing nanosized Rb is challenging. This study proposes a sample solid-liquid transformation and ultrasonic dispersion method to prepare Rb nanoparticles (NPs) utilizing Rb's low melting point. This method uses the ultrasonic emulsification of liquid Rb in a specific liquid (toluene) to form a colloidal Rb solution. Typically prepared Rb NPs are nearly spherical with an average size of approximately 45 nm. Further, the average size increases with a decrease in ultrasonic power. When the ultrasonic power falls to 320 and 240 W, the average NP size rises to 55 and 70 nm, respectively, demonstrating good controllability of the proposed method. Further experiments demonstrated that Rb NPs can ignite toluene at relatively low temperatures (say 120^oC) within 1 s. When the temperature is up to 250^oC, toluene can be ignited in 0.25 s. This study not only provides a new method for synthesizing Rb NPs but also offers new opportunities for novel energy-containing materials and ignition devices.

Key words： rubidium nanoparticle sol ultrasonic emulsification ignition performance

收稿日期: 2021-01-05

ZTFLH:

O611.4

基金资助:河北省重点研发计划项目(19211002D)

作者简介: 郭雨静,女,1997年生,硕士生

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https://www.ams.org.cn/CN/10.11900/0412.1961.2021.00001 或 https://www.ams.org.cn/CN/Y2022/V58/I6/792

图1 固/液转变+超声分散法制备Rb纳米溶胶的示意图

图2 所制备的Rb溶胶的光学吸收谱、溶胶装在样品瓶中光学照片及稀释10倍后的Tyndall效应

图3 所制备的Rb溶胶中产物的表征

图4 不同超声功率下获得的溶胶的光学吸收谱、溶胶中产物的TEM像及粒径统计

图5 Rb纳米溶胶的形成过程示意图

图6 将300 μL的甲苯/金属Rb纳米溶胶置于120℃的陶瓷舟中不同时间的点火特性

图7 金属Rb纳米溶胶在不同温度的点火时间

图8 在120℃陶瓷舟中的溶胶液膜的形态演变及引燃示意图

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