Document Type
Article
Publication Date
2025
DOI
10.26434/chemrxiv-2025-3wl26
Publication Title
ChemRxiv
Pages
1-24
Abstract
Per- and polyfluoroalkyl substances (PFAS) contamination has posed a significant environmental and public health challenge due to their ubiquitous nature. Adsorption has emerged as a promising remediation technique, yet optimizing adsorption efficiency remains complex due to the diverse physicochemical properties of PFAS and the wide range of adsorbent materials. Traditional modeling approaches, such as response surface methodology (RSM), struggled to capture nonlinear interactions, while standalone machine learning (ML) models required extensive datasets. This study addressed these limitations by developing hybrid RSM-ML models to improve the prediction and optimization of PFAS adsorption. A comprehensive dataset was constructed using experimental adsorption data, integrating key parameters such as pH, pHpzc, surface area, temperature, and PFAS molecular properties. RSM was employed to model adsorption behavior, while gradient boosting (GB), random forest (RF), and extreme gradient boosting (XGB) were used to enhance predictive performance. Hybrid models—linear, RMSE-based, multiplicative, and meta-learning—were developed and evaluated. The meta-learning HOP-RSM-GB model achieved near-perfect accuracy (R² = 1.00, RMSE = 10.59), outperforming all other models. Surface plots revealed that low pH and high pHpzc maximized the adsorption while increasing log Kow consistently enhanced PFAS adsorption. These findings establish hybrid RSM-ML modeling as a powerful framework for optimizing PFAS remediation strategies. The integration of statistical and machine learning approaches significantly improves predictive accuracy, reduces experimental costs, and provides deeper insights into adsorption mechanisms. This study underscores the importance of data-driven approaches in environmental engineering and highlights future opportunities for integrating ML-driven modeling with experimental adsorption research.
Rights
© 2025 The Authors.
This content is available under a Creative Commons Attribution 4.0 International (CC BY 4.0) License.
Original Publication Citation
Patel, H. V., Green, J., Park, J., Pass, S. L.-T., & Zhao, R. (2025). Quantifying multidimensional effects of physicochemical parameters on PFAS adsorption using a hybrid response surface methodology-machine learning approach. ChemRxiv. https://doi.org/10.26434/chemrxiv-2025-3wl26
Repository Citation
Patel, Harsh V.; Green, Jazmin; Park, John; Pass, Stephanie Luster-Teasley; and Zhao, Renzun, "Quantifying Multidimensional Effects of Physicochemical Parameters on PFAS Adsorption Using a Hybrid Response Surface Methodology-Machine Learning Approach" (2025). Engineering Management & Systems Engineering Faculty Publications. 226.
https://digitalcommons.odu.edu/emse_fac_pubs/226
Included in
Artificial Intelligence and Robotics Commons, Materials Science and Engineering Commons, Public Health Commons, Water Resource Management Commons
Comments
This content is a pre-print and has not undergone peer review at the time of posting.