Universal Model for Predicting Maximum Spreading of Drop Impact on a Smooth Surface Developed Using Boosting Machine Learning Models

Abstract: Drop impact on a solid surface is a fundamental phenomenon in nature and engineering. Prediction of the maximum spreading ratio during drop impact is critical for modeling and optimizing the relevant processes. However, accurately modeling the maximum spreading using empirical and numerical methods remains challenging. Machine learning (ML) has recently provided a promising way to understand and model complex fluid phenomena. Thus, in this study, a universal model is developed by using machine learning methods… Show more

“…Regarding rough and superhydrophobic surfaces, Wang et al found that surface roughness minimally affects the spreading diameter of dilute SDS droplets on micropillared arrays . However, higher surfactant concentrations decrease the droplet-receding velocity and can prevent bouncing on superhydrophobic surfaces. ,, Additionally, surfactant molecules entering micro or nanostructures on superhydrophobic surfaces change the surface wettability, with faster impact speeds enhancing this interaction. − Efforts at developing a prediction of maximum spreading ratios are numerous and take into account a variety of variables (fluid properties or wetting characteristics) but generally do not account for the unique properties of surfactant-laden liquids. − …”

“… 43 − 46 Efforts at developing a prediction of maximum spreading ratios are numerous and take into account a variety of variables (fluid properties or wetting characteristics) but generally do not account for the unique properties of surfactant-laden liquids. 47 − 49 …”

Effect of Surfactants on the Splashing Dynamics of Drops Impacting Smooth Substrates

“…Regarding rough and superhydrophobic surfaces, Wang et al found that surface roughness minimally affects the spreading diameter of dilute SDS droplets on micropillared arrays . However, higher surfactant concentrations decrease the droplet-receding velocity and can prevent bouncing on superhydrophobic surfaces. ,, Additionally, surfactant molecules entering micro or nanostructures on superhydrophobic surfaces change the surface wettability, with faster impact speeds enhancing this interaction. − Efforts at developing a prediction of maximum spreading ratios are numerous and take into account a variety of variables (fluid properties or wetting characteristics) but generally do not account for the unique properties of surfactant-laden liquids. − …”

“… 43 − 46 Efforts at developing a prediction of maximum spreading ratios are numerous and take into account a variety of variables (fluid properties or wetting characteristics) but generally do not account for the unique properties of surfactant-laden liquids. 47 − 49 …”

Effect of Surfactants on the Splashing Dynamics of Drops Impacting Smooth Substrates

Physics-constrained extreme gradient boosting model for steam condensation heat transfer prediction over a vertical tube in the presence of noncondensable gas

Predicting Energy Budgets in Droplet Dynamics: A Recurrent Neural Network Approach