Deep Learning Approaches for Predicting the Surface Tension of Ionic Liquids.
Journal:
Journal of chemical information and modeling
Published Date:
Jun 6, 2025
Abstract
Ionic liquids (ILs) are a novel class of solvents that have attracted significant attention due to their unique and tunable properties. Among their physiochemical characteristics, surface tension plays a critical role in various industrial applications including electrolytes, heat transfer fluids, and separation processes. However, because of the exploratory nature of IL design and the vast combinatorial space of possible anion-cation pairs, the experimental determination of these properties is often impractical, being both time-consuming and costly. To overcome these challenges, computational approaches are increasingly employed to develop accurate predictive models that can accelerate IL discovery and design. In this study, we present two deep learning (DL) models for predicting the surface tension of ILs across a broad temperature range at a constant pressure. The models use simplified molecular input line entry system, SMILES, representations of ILs to extract molecular features as inputs. Both DL models demonstrate excellent agreement with experimental data, achieving an value of 0.990 and a root-mean-square error of 0.792 mN/m. These results offer valuable insights for the rapid screening and rational design of ILs with tailored surface tension values.
