<HashMap><database>biostudies-literature</database><scores/><additional><submitter>Pandey DK</submitter><funding>Taighde Éireann – Research Ireland</funding><pagination>107325</pagination><full_dataset_link>https://www.ebi.ac.uk/biostudies/studies/S-EPMC11987696</full_dataset_link><repository>biostudies-literature</repository><omics_type>Unknown</omics_type><volume>116</volume><pubmed_abstract>Cavitation is increasingly being used for producing liquid-liquid emulsions. Cavity collapse generates microscale high-speed jets, which play a crucial role in cavitation-driven emulsification. It is thus essential to investigate the interaction of cavity and droplet to improve the understanding of the cavitation-driven emulsification process. In this study, we have numerically investigated the interaction of a single cavity-droplet pair dispersed in a water medium mimicking the scenario occurring inside a hydrodynamic cavitation-based fluidic device. A direct numerical simulation utilizing the multi-fluid, volume of fluid (VOF) method has been used for simulating different scenarios of cavity droplet interactions. The effect of the droplet-cavity size ratio (β) and the stand-off parameter (γ) on cavity-droplet dynamics have been investigated. The influence of these parameters on cavity jet velocity U&lt;sub>max&lt;/sub> and energy dissipation rate (ε) was evaluated. Cavity jet velocity (U&lt;sub>max&lt;/sub>) increases at first, then decreases with the stand-off parameter whereas it increases and becomes almost constant for the size ratio. The maximum cavity jet velocity in the present work is obtained for the case β=2.5(γ=0.7) and β=5(γ=1.2). The energy dissipation rate for cavity-oil droplet interaction is of the order 10&lt;sup>8&lt;/sup> m&lt;sup>2&lt;/sup>/s&lt;sup>3&lt;/sup>, irrespective of the stand-off parameter and size ratio for a given driving force. The results presented in this work improve the current fundamental understanding of cavity-drop interactions and provide a useful basis for developing cavitation-induced droplet breakage models for predicting droplet size distributions, enabling enhanced applications of cavitation for emulsification in the chemical industries.</pubmed_abstract><journal>Ultrasonics sonochemistry</journal><pubmed_title>Understanding cavity dynamics near deformable oil drop via numerical simulations.</pubmed_title><pmcid>PMC11987696</pmcid><funding_grant_id>20/FFP-A/8518</funding_grant_id><pubmed_authors>Pandey DK</pubmed_authors><pubmed_authors>Ranade VV</pubmed_authors><pubmed_authors>Kumar R</pubmed_authors></additional><is_claimable>false</is_claimable><name>Understanding cavity dynamics near deformable oil drop via numerical simulations.</name><description>Cavitation is increasingly being used for producing liquid-liquid emulsions. Cavity collapse generates microscale high-speed jets, which play a crucial role in cavitation-driven emulsification. It is thus essential to investigate the interaction of cavity and droplet to improve the understanding of the cavitation-driven emulsification process. In this study, we have numerically investigated the interaction of a single cavity-droplet pair dispersed in a water medium mimicking the scenario occurring inside a hydrodynamic cavitation-based fluidic device. A direct numerical simulation utilizing the multi-fluid, volume of fluid (VOF) method has been used for simulating different scenarios of cavity droplet interactions. The effect of the droplet-cavity size ratio (β) and the stand-off parameter (γ) on cavity-droplet dynamics have been investigated. The influence of these parameters on cavity jet velocity U&lt;sub>max&lt;/sub> and energy dissipation rate (ε) was evaluated. Cavity jet velocity (U&lt;sub>max&lt;/sub>) increases at first, then decreases with the stand-off parameter whereas it increases and becomes almost constant for the size ratio. The maximum cavity jet velocity in the present work is obtained for the case β=2.5(γ=0.7) and β=5(γ=1.2). The energy dissipation rate for cavity-oil droplet interaction is of the order 10&lt;sup>8&lt;/sup> m&lt;sup>2&lt;/sup>/s&lt;sup>3&lt;/sup>, irrespective of the stand-off parameter and size ratio for a given driving force. The results presented in this work improve the current fundamental understanding of cavity-drop interactions and provide a useful basis for developing cavitation-induced droplet breakage models for predicting droplet size distributions, enabling enhanced applications of cavitation for emulsification in the chemical industries.</description><dates><release>2025-01-01T00:00:00Z</release><publication>2025 May</publication><modification>2025-07-05T03:04:28.817Z</modification><creation>2025-07-05T03:04:28.817Z</creation></dates><accession>S-EPMC11987696</accession><cross_references><pubmed>40153969</pubmed><doi>10.1016/j.ultsonch.2025.107325</doi></cross_references></HashMap>