A new model of bi-component droplet heating and evaporation

Dmitry Antonov; Simona Tonini; Gianpietro E Cossali; Sergei Sazhin

doi:10.1063/5.0278893

A new model of bi-component droplet heating and evaporation

Dmitry Antonov
, Simona Tonini
, Gianpietro E Cossali
, Sergei Sazhin

Research output: Contribution to journal › Article › peer-review

Abstract

A new model of bi-component droplet heating and evaporation is described. The model considers the effects of temperature gradient and component diffusion in the liquid and gas phases assuming that all processes are spherically symmetric. The simplified forms of heat transfer and component diffusion equations were solved analytically in the liquid phase and numerically in the gas phase at each timestep. These solutions were implemented in the numerical
code, predicting the time evolution of the distribution of droplet temperatures in the liquid and gas phases and the droplet evaporation rate. The model predictions were verified in the limiting case, when one component was used, using the predictions of the earlier developed model for mono-component droplet heating and evaporation. For the bicomponent droplets, they were verified using COMSOL Multiphysics calculations. The validation of model predictions was performed using in-house experimental data.

Original language	English
Article number	073361
Journal	Physics of Fluids
Volume	37
Issue number	7
DOIs	https://doi.org/10.1063/5.0278893
Publication status	Published - 23 Jul 2025

Bibliographical note

Publisher Copyright:
© 2025 Author(s).

Keywords

diffusion rate
transport properties
heat transfer
thermocouples
MATLAB
numerical algorithms
mathematical modeling
gas phase
liquid-vapor interface
computational fluid dynamics

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10.1063/5.0278893

Dmitrii_Simona_29May25-CleanAccepted author manuscript, 3.35 MBLicence: Unspecified

Cite this

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title = "A new model of bi-component droplet heating and evaporation",

abstract = "A new model of bi-component droplet heating and evaporation is described. The model considers the effects of temperature gradient and component diffusion in the liquid and gas phases assuming that all processes are spherically symmetric. The simplified forms of heat transfer and component diffusion equations were solved analytically in the liquid phase and numerically in the gas phase at each timestep. These solutions were implemented in the numerical code, predicting the time evolution of the distribution of droplet temperatures in the liquid and gas phases and the droplet evaporation rate. The model predictions were verified in the limiting case, when one component was used, using the predictions of the earlier developed model for mono-component droplet heating and evaporation. For the bicomponent droplets, they were verified using COMSOL Multiphysics calculations. The validation of model predictions was performed using in-house experimental data.",

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author = "Dmitry Antonov and Simona Tonini and Cossali, \{Gianpietro E\} and Sergei Sazhin",

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doi = "10.1063/5.0278893",

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T1 - A new model of bi-component droplet heating and evaporation

AU - Antonov, Dmitry

AU - Tonini, Simona

AU - Cossali, Gianpietro E

AU - Sazhin, Sergei

PY - 2025/7/23

Y1 - 2025/7/23

N2 - A new model of bi-component droplet heating and evaporation is described. The model considers the effects of temperature gradient and component diffusion in the liquid and gas phases assuming that all processes are spherically symmetric. The simplified forms of heat transfer and component diffusion equations were solved analytically in the liquid phase and numerically in the gas phase at each timestep. These solutions were implemented in the numerical code, predicting the time evolution of the distribution of droplet temperatures in the liquid and gas phases and the droplet evaporation rate. The model predictions were verified in the limiting case, when one component was used, using the predictions of the earlier developed model for mono-component droplet heating and evaporation. For the bicomponent droplets, they were verified using COMSOL Multiphysics calculations. The validation of model predictions was performed using in-house experimental data.

AB - A new model of bi-component droplet heating and evaporation is described. The model considers the effects of temperature gradient and component diffusion in the liquid and gas phases assuming that all processes are spherically symmetric. The simplified forms of heat transfer and component diffusion equations were solved analytically in the liquid phase and numerically in the gas phase at each timestep. These solutions were implemented in the numerical code, predicting the time evolution of the distribution of droplet temperatures in the liquid and gas phases and the droplet evaporation rate. The model predictions were verified in the limiting case, when one component was used, using the predictions of the earlier developed model for mono-component droplet heating and evaporation. For the bicomponent droplets, they were verified using COMSOL Multiphysics calculations. The validation of model predictions was performed using in-house experimental data.

KW - diffusion rate

KW - transport properties

KW - heat transfer

KW - thermocouples

KW - MATLAB

KW - numerical algorithms

KW - mathematical modeling

KW - gas phase

KW - liquid-vapor interface

KW - computational fluid dynamics

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JO - Physics of Fluids

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A new model of bi-component droplet heating and evaporation

Abstract

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Keywords

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