Leidenfrost phenomenon during quenching in aqueous solutions: effect of evaporation-induced concentration gradients

The minimum temperature limit for a sustained vapor film on a hot surface defines the well-known Leidenfrost temperature (LFT). LFT for pure fluids is typically a strong function of the surface tension. However, the effect of surface tension on LFT of aqueous additive solutions is confusing with man...

Full description

Saved in:
Bibliographic Details
Published in:Soft matter 2020-07, Vol.16 (26), p.6145-6154
Main Authors: Kumar, Vijay, Sinha, Kumar Nishant Ranjan, Raj, Rishi
Format: Article
Language:English
Subjects:
Additives
Aqueous solutions
Computational fluid dynamics
Concentration gradient
Evaporation
Hot surfaces
Ionic liquids
Leidenfrost phenomenon
Quenching
Surface tension
Surfactants
Temperature
Tension
Vapors
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:The minimum temperature limit for a sustained vapor film on a hot surface defines the well-known Leidenfrost temperature (LFT). LFT for pure fluids is typically a strong function of the surface tension. However, the effect of surface tension on LFT of aqueous additive solutions is confusing with many complicated trends. For example, despite an insignificant increase of 1 mN m −1 in surface tension, a substantial increase in LFT of 50 °C with aqueous salt and sugar solutions has been reported in comparison to pure water. Conversely, no appreciable change in LFT (within ±2 °C) is observed despite a substantial drop of up to 30 mN m −1 in surface tension upon varying the concentration of surfactant additives in aqueous solutions. Here, we perform simultaneous thermal, visual, and acoustic characterization of pool quenching experiments with aqueous solutions of salt, sugar, surfactant, and ionic liquids. We model the evaporation-induced increase in the concentration of the non-volatile additives at the liquid-vapor interface using Fick's second law of diffusion. We show that the localized concentration buildup of additives at the liquid-vapor interface dramatically alters the surface tension values in comparison to the typical equilibrium values estimated otherwise. We use these modified surface tension values to correlate the diverse set of experimental LFT data reported in our work and in the literature using a unified framework. We believe that these clarifications regarding the Leidenfrost mechanism will encourage the use of additives in various applications, specifically those where surface modification strategies may not be practically feasible. We present a unified framework to elucidate the effect of evaporation-induced concentration gradient of various types of additives on the modification of the Leidenfrost temperature during quenching in aqueous solutions.
ISSN:1744-683X
1744-6848
DOI:10.1039/d0sm00622j