How Nanoparticle Size and Bubble Merging Is Governed by Short-Range Spatially Controlled Double-Beam Laser Ablation in Liquids

Pulsed laser ablation in liquid (LAL) is a method for synthesizing nanoparticles with controlled composition and high purity. However, current research predominantly examines isolated cavitation bubbles, overlooking real-world LAL scenarios where numerous bubbles interact simultaneously. This study addresses this gap by investigating the effects of short-range micrometric spatially controlled double-pulse laser ablation in liquids on nanoparticle size distribution. Gold and YAG are used as model materials, and a dimensionless parameter, H*, is introduced to quantify the ratio between double bubble spatial separation and their maximum height. This parameter correlates with cavitation bubble merging time, bubble volume change rate, and subsequent nanoparticle size increase. Shadowgraphs provide valuable insights into bubble contact and fusion dynamics, showcasing phase separation by a thin water film and subsequent merging into a single bubble. Notably, a twofold increase in nanoparticle size is observed for both Au and YAG at H* = 0.25. The research indicates a strong association between nanoparticle size trends and cavitation bubble volume rate change, particularly emphasized at H* = 0.25. Understanding the dynamics of neighboring bubbles during LAL emphasizes the relevance of lateral pulse distances in dual-beam LAL, impacting particle size distribution in a distance-dependent manner. This study explores the impact of short-range micrometric controlled double-pulse laser ablation in liquids on nanoparticle size distribution. The defined dimensionless parameter H* quantifies the spatial separation between two bubbles, correlating with bubble dynamics and nanoparticle size. A twofold increase in nanoparticle size is observed at H* = 0.25, emphasizing the relevance of lateral pulse separation towards nanoparticle size control.image