Energy Safety Research Institute (ESRI), Swansea University Bay Campus, Fabian Way, Swansea SA1 8EN, United Kingdom.
Energy Safety Research Institute (ESRI), Swansea University Bay Campus, Fabian Way, Swansea SA1 8EN, United Kingdom; Department of Chemistry, Rice University, Houston, TX 77005, USA; Department of Materials Science and Nanoengineering, Rice University, Houston, TX 77005, USA.
J Colloid Interface Sci. 2020 May 1;567:45-53. doi: 10.1016/j.jcis.2020.01.116. Epub 2020 Jan 30.
Nanoparticle embedding into the surface of plastics provides an effective anchor that improves the durability of coatings formed from functionalized nanoparticles. Coatings formed from thermally embedded particles show superior wear resistance relative to coatings formed from non-embedded particles. As a consequence of this, embedded nanoparticles functionalized with hydrophilic and hydrophobic carboxylates are better suited for controlling the wettability of plastics than when the nanoparticles are deposited onto the plastic under ambient conditions.
Carboxylate-functionalized AlO nanoparticles were embedded into ethylene vinyl acetate through spray coating the particles onto the substrate during heating. Sonication was used to remove excess particles that did not become embedded into the material. Coatings formed from the embedded particles were characterized through scanning electron microscopy (SEM), atomic force microscopy (AFM), energy dispersive X-ray spectroscopy (EDX), and X-ray photoelectron spectroscopy (XPS). The wettability of the coatings was characterized using static and dynamic contact angle (CA) measurements to measure the apparent water contact angles, and sliding angle measurements, whilst the durability of the coatings was studied using scratch testing, tape peel tests, and abrasion tests. The build-up of fog on the substrates was also studied through exposing the surfaces to water vapour.
Thermal embedding of the particles into the surface of the plastic was observed to occur when the material was heated to temperatures around its melting temperature. AFM and SEM showed that plastic embedded with the nanoparticles possessed a morphology that was substantially rougher than the untreated plastic. CA measurements showed that plastic embedded with hydrophobic isostearate functionalized nanoparticles was highly hydrophobic and displayed a CA of approximately 152°. Dynamic CA measurements and sliding angle measurements revealed that plastic embedded with the isostearate functionalized nanoparticles showed petal-like wetting behavior. Furthermore, it was observed that the CA of the plastic could be varied from highly hydrophobic to highly hydrophilic through embedding varying amounts of isostearate and hydrophilic 2-[2-(2-methoxyethoxy)ethoxy]acetate functionalized AlO nanoparticles into the surface of the material. Scratch testing showed that thermally embedding the nanoparticles into the plastic substantially improved their abrasion resistance, relative to when the nanoparticles are deposited onto the non-heated material. This methodology indicates that embedding nanoparticles into plastics creates durable coatings that can display variable wettability. Consequently, this methodology could be useful in applications where it is desirable to keep plastics dry, such as for food packaging or medical devices.
将纳米粒子嵌入塑料表面提供了一种有效的锚点,可以提高由功能化纳米粒子形成的涂层的耐久性。与由未嵌入粒子形成的涂层相比,由热嵌入粒子形成的涂层显示出更高的耐磨性。因此,用亲水性和疏水性羧酸官能化的嵌入纳米粒子比在环境条件下将纳米粒子沉积到塑料上更适合控制塑料的润湿性。
通过在加热过程中将粒子喷涂到基底上,将羧酸官能化的 AlO 纳米粒子嵌入乙烯-醋酸乙烯酯中。超声处理用于去除未嵌入材料的多余颗粒。通过扫描电子显微镜(SEM)、原子力显微镜(AFM)、能量色散 X 射线光谱(EDX)和 X 射线光电子能谱(XPS)对由嵌入粒子形成的涂层进行了表征。使用静态和动态接触角(CA)测量来测量表观水接触角以及滑动角测量来表征涂层的润湿性,同时通过划痕试验、胶带剥离试验和磨损试验来研究涂层的耐久性。还通过将表面暴露于水蒸气来研究基底上雾的形成。
当材料加热到接近其熔点的温度时,观察到粒子热嵌入塑料表面。AFM 和 SEM 表明,用纳米粒子嵌入的塑料具有比未处理的塑料明显粗糙的形态。CA 测量表明,用疏水性异硬脂酸官能化纳米粒子嵌入的塑料具有高度疏水性,并且显示出约 152°的 CA。动态 CA 测量和滑动角测量表明,用异硬脂酸官能化纳米粒子嵌入的塑料表现出花瓣状的润湿行为。此外,观察到通过将不同量的异硬脂酸和亲水性 2-[2-(2-甲氧基乙氧基)乙氧基]乙酸盐官能化 AlO 纳米粒子嵌入材料表面,可以将塑料的 CA 从高度疏水性变为高度亲水性。划痕试验表明,与将纳米粒子沉积到未加热的材料上相比,将纳米粒子热嵌入塑料可大大提高其耐磨性。该方法表明,将纳米粒子嵌入塑料中可以形成耐用的涂层,并且可以显示出可变化的润湿性。因此,该方法在需要保持塑料干燥的应用中可能很有用,例如在食品包装或医疗设备中。
