Prediction of hydroxyl radical exposure during ozonation using different machine learning methods with ozone decay kinetic parameters

Dongwon Cha, Sanghun Park, Min Sik Kim, Jaesang Lee, Yunho Lee, Kyung Hwa Cho, Changha Lee

    Research output: Contribution to journalArticlepeer-review

    Abstract

    The abatement of micropollutants by ozonation can be accurately calculated by measuring the exposures of molecular ozone (O3) and hydroxyl radical (OH) (i.e., ∫[O3]dt and ∫[OH]dt). In the actual ozonation process, ∫[O3]dt values can be calculated by monitoring the O3 decay during the process. However, calculating ∫[OH]dt is challenging in the field, which necessitates developing models to predict ∫[OH]dt from measurable parameters. This study demonstrates the development of machine learning models to predict ∫[OH]dt (the output variable) from five basic input variables (pH, dissolved organic carbon concentration, alkalinity, temperature, and O3 dose) and two optional ones (∫[O3]dt and instantaneous ozone demand, IOD). To develop the models, four different machine learning methods (random forest, support vector regression, artificial neural network, and Gaussian process regression) were employed using the input and output variables measured (or determined) in 130 different natural water samples. The results indicated that incorporating ∫[O3]dt as an input variable significantly improved the accuracy of prediction models, increasing overall R2 by 0.01−0.09, depending on the machine learning method. This suggests that ∫[O3]dt plays a crucial role as a key variable reflecting the OH-yielding characteristics of dissolved organic matter. Conversely, IOD had a minimal impact on the accuracy of the prediction models. Generally, machine-learning-based prediction models outperformed those based on the response surface methodology developed as a control. Notably, models utilizing the Gaussian process regression algorithm demonstrated the highest coefficients of determination (overall R2 = 0.91−0.95) among the prediction models.

    Original languageEnglish
    Article number122067
    JournalWater Research
    Volume261
    DOIs
    Publication statusPublished - 2024 Sept 1

    Bibliographical note

    Publisher Copyright:
    © 2024 Elsevier Ltd

    Keywords

    • Instantaneous ozone demand
    • Machine learning
    • Micropollutant abatement
    • Modeling
    • Oxidant exposure
    • Ozonation

    ASJC Scopus subject areas

    • Environmental Engineering
    • Civil and Structural Engineering
    • Ecological Modelling
    • Water Science and Technology
    • Waste Management and Disposal
    • Pollution

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