Controlling the size distribution of nanoparticles through the use of physical boundaries during laser ablation in liquids

TL;DR

This study demonstrates that physical boundaries during laser ablation in liquids can effectively control nanoparticle size distribution, with boundaries leading to larger mean sizes due to prolonged plasma thermalisation.

Contribution

The paper introduces a simple method of using physical boundaries to control nanoparticle sizes during laser ablation, showing consistent size increases across different materials and liquids.

Findings

Physical boundaries increase nanoparticle mean size.

Size increase is linked to prolonged plasma thermalisation.

Effect varies with target material and liquid medium.

Abstract

A simple, yet effective method of controlling the size and size distributions of nanoparticles produced as a result of laser ablation of target material is presented. The method employs the presence of physical boundaries on either sides of the ablation site. In order to demonstrate the potential of the method, experiments have been conducted with copper and titanium as the target materials that are placed in two different liquid media (water and isopropyl alcohol). The ablation of the target material immersed in the liquid medium has been carried out using an Nd:YAG laser. Significant differences in the size and size distributions are observed in the cases of nanoparticles produced with and without confining boundaries. It is seen that for any given liquid medium and the target material, the mean size of the nanoparticles obtained with the boundary-fitted target surface is consistently higher than that achieved in the case of open (flat) targets. The observed trend has been attributed to the plausible role(s) of the confining boundaries in prolonging the thermalisation time of the plasma plume. In order to ascertain that the observed differences in sizes of the nanoparticles produced with and without the presence of the physical barriers are predominantly because of the prolonged thermalisation of the plasma plume and not due to the possible formation of oxide layer, select experiments with gold as the target material in water have also been performed. The experiments also show that, irrespective of the liquid medium, the increase in the mean size of the copper-based nanoparticles due to the presence of physical boundaries is relatively higher than that observed in the case of titanium target material under similar experimental conditions.