Abstract
Efficient encapsulation of small chemical molecules and their controlled targeted delivery provides a very important challenge to be overcome for a wide range of industrial applications. Typically rapid diffusion of these actives across capsule walls has so far prevented the development of a versatile widely applicable solution. In an earlier publication, we have shown that thin metal shells are able to permanently retain small molecules. The critical step in the microcapsule synthesis is the formation of a strongly adsorbed, dense monolayer of catalytic nanoparticles on the surface as this affects the secondary metal film quality. Control over Pt-nanoparticle adsorption density and a clear understanding of Pt-nanoparticle adsorption kinetics is therefore paramount. Maximising the density of heterogeneous catalysts on surfaces is generally of interest to a broad range of applications. In this work, transmission electron microscopy (TEM) and quartz crystal microbalance (QCM) are used to demonstrate that the concentration of nanoparticle polymer stabilizer used during particle synthesis and nanoparticle suspension concentration can be used to control nanoparticle surface adsorption density. We demonstrate that excess polymer, which is often used in nanoparticle synthesis but rarely discussed as an important parameter in the literature, can compete with and thus drastically affect the adsorption of the Pt-nanoparticles.
Highlights
Efficient encapsulation of chemicals and their controlled targeted delivery is an area of significant academic and industrial interest
This part of the work focused on developing a nanoparticle synthesis protocol to control both the concentration of stabilizing polymer and the nanoparticle diameter
We have studied the adsorption of sterically stabilized metallic nanoparticles onto polymeric substrates, which is an important process used to physically immobilize catalytic nanoparticles on surfaces
Summary
Efficient encapsulation of chemicals and their controlled targeted delivery is an area of significant academic and industrial interest. Significant challenges remain for the encapsulation of low molecular weight molecules, as typical polymer microcapsule shells cannot prevent leaching of such core materials. In a previous research article,[1] we developed a method for the efficient encapsulation of small volatile molecules using impermeable metal shells. The 2D surface density and the homogeneity of the adsorbed nanoparticles are the key variables that affect the quality of the subsequently deposited continuous metal films. A good understanding of the nanoparticle adsorption kinetics and energetics and their influence over the adsorption is paramount if we are to achieve reliable permanent encapsulation of the active molecules in the core. This article investigates the various parameters that can influence the adsorption process so that the final adsorbed nanoparticle density can be controlled efficiently
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