Rarefied gas flow past a liquid droplet: interplay between internal and external flows

TL;DR

This paper investigates how internal liquid motion and kinetic effects influence the drag force and temperature distribution on microdroplets in rarefied gas flows, combining analytical models with existing experimental data.

Contribution

It introduces an analytical model accounting for internal liquid motion and kinetic effects in rarefied gas flow over droplets, extending understanding of droplet dynamics at micro and nanoscales.

Findings

Drag force aligns with existing theories and experiments.

Internal motion significantly affects temperature profiles.

Kinetic effects alter flow characteristics at small scales.

Abstract

Experimental and theoretical studies on millimetre-sized droplets suggest that at low Reynolds number the difference between the drag force on a circulating water droplet and that on a rigid sphere is very small (less than 1 %) (LeClair et al., J. Atmos. Sci., vol. 29, 1972, pp. 728-740). While the drag force on a spherical liquid droplet at high viscosity ratios (of the liquid to the gas), is approximately the same as that on a rigid sphere of the same size, the other quantities of interest (e.g. the temperature) in the case of a rarefied gas flow over a liquid droplet differ from the same quantities in the case of a rarefied gas flow over a rigid sphere. The goal of this article is to study the effects of internal motion within a spherical microdroplet/nanodroplet -- such that its diameter is comparable to the mean free path of the surrounding gas -- on the drag force and its overall dynamics. To this end, the problem of a slow rarefied gas flowing over an incompressible liquid droplet is investigated analytically by considering the internal motion of the liquid inside the droplet and also by accounting for kinetic effects in the gas. Detailed results for different values of the Knudsen number, the ratio of the thermal conductivities and the ratio of viscosities are presented for the pressure and temperature profiles inside and outside the liquid droplet. The results for the drag force obtained in the present work are in good agreement with the theoretical and experimental results existing in the literature.