SiO2颗粒分散液浓度对建筑结构钢锌系复合磷化膜耐蚀性的影响

通过硫酸铜点滴实验、静态浸泡实验以及电化学阻抗谱测试,以变色时间、电荷转移电阻、低频阻抗模值等作为指标,研究了SiO2颗粒分散液浓度对锌系复合磷化膜耐蚀性的影响。结果表明:SiO2颗粒分散液浓度对磷化膜的耐蚀性有较显著的影响,随着SiO2颗粒分散液浓度从10 mL/L增加到60 mL/L,磷化膜变色时间从116 s逐渐延长到170 s,电荷转移电阻从1.170 kΩ·cm2逐渐增大到4.580 kΩ·cm2,低频阻抗模值从0.635 kΩ·cm2逐渐增大到3.845 kΩ·cm2,说明磷化膜的耐蚀性有较大幅度提高。随着SiO2颗粒分散液浓度从60 mL/L继续增加到80 mL/L,磷化膜变色时间、电荷转移电阻和低频阻抗模值都变化不大,其耐蚀性未进一步提高。但SiO2颗粒分散液浓度超过80 mL/L后,磷化膜的耐蚀性明显变差。

pH响应型P(HEMA/MAA)纳米微凝胶分散液的凝胶化行为和流变性能

制备了在修复受损组织方面有应用潜能的纳米级聚(甲基丙烯酸羟乙酯/甲基丙烯酸)(P(HEMA/MAA))微凝胶;采用试管倒转法对不同pH值和浓度的P(HEMA/MAA)微凝胶分散液的凝胶化相转变行为进行了研究;借助椎板流变仪考察了低浓度和高浓度微凝胶分散液的流变性能,并对pH触发物理凝胶化相转变机理进行了推测.结果表明:在生理pH值环境下,一定浓度的P(HEMA/MAA)微凝胶分散液可以发生凝胶化相转变形成凝胶态,pH=7时,HEMA/MAA进料摩尔比为8/2的微凝胶分散液凝胶化后得到的凝胶力学性能最佳,最大弹性模量(G')可达7.58×103Pa;P(HEMA/MAA)微凝胶颗粒在不同条件下具有不同的溶胀效果,导致低浓度分散液的表观粘度发生相应的变化,并由此推测出微凝胶颗粒的溶胀过程由外及内,分为三个阶段;高浓度微凝胶分散液发生凝胶化相转变主要是由颗粒间或颗粒与分散介质间形成的空间静电稳定作用和氢键共同作用引起的.

氧化石墨烯和石墨烯的高浓度加工、致密化及应用

由紧密堆叠的石墨烯片组成的致密石墨烯组件具有出色的化学稳定性和优异的力学、热学和电学性能。致密石墨烯组件不存在多孔石墨烯气凝胶中密度低、力学强度低、导电性差和导热性差等问题,是未来便携式电子和智能设备的理想材料。本文对制备方法进行了总结,包括利用机械分散、蒸发浓缩、离心浓缩和液相剥离法获得的高浓度氧化石墨烯(GO)和石墨烯分散液,以及利用真空辅助过滤、界面自组装和压制成型法获得的二维(2D)致密石墨烯基薄膜和三维(3D)致密石墨烯基结构,并评估了各种方法的优缺点。此外,还总结了致密石墨烯基组件在储能、热管理和电磁干扰(EMI)屏蔽方面的应用。最后,概述了致密石墨烯组件在未来研究中面临的挑战和前景。本综述为探索和开发大规模、低成本的制造技术和面向应用的致密石墨烯组件提供参考。

Separation of Eu^3＋ Using a Novel Dispersion Combined Liquid Membrane with P507 in Kerosene as the Carrier

The separation of Eu^3 ＋is studied with a dispersion combined liquid membrane（DCLM）,in which polyvinylidene fluoride membrane（PVDF）is used as the liquid membrane support,dispersion solution containing HCl solution as the stripping solution,and 2-ethyl hexyl phosphonic acid-mono-2-ethyl hexyl ester（P507）dissolved in kerosene as the membrane solution.The effects of pH value,initial concentration of Eu3 ＋and different ionic strength in the feed phase,volume ratio of membrane solution to stripping solution,concentration of HCl solution, concentration of carrier,different stripping agents in the dispersion phase on the separation are investigated.The optimum condition for separation of Eu3 ＋is that concentration of HCl solution is 4.0 mol·L 1,concentration of carrier is 0.16 mol·L 1,and volume ratio of membrane solution to stripping solution is 30︰30 in the dispersion phase, and pH value is 4.2 in the feed phase.The ionic strength has no significant effect on separation of Eu3 ＋.Under the optimum condition,when the initial concentration of Eu3 ＋is 0.8×10 4mol·L 1,the separation percentage of Eu 3＋is 95.3%during the separation time of 130 min.The kinetic equation is developed in terms of the law of mass diffusion and the theory of interface chemistry.The diffusion coefficient of Eu3 ＋in the membrane and the thickness of diffusion layer between feed phase and membrane phase are obtained and their values are 1.48×10 7m 2·s 1and 36.6μm,respectively.The results obtained are in good agreement with literature data.