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Machine learning and thermodynamic modeling for optimizing hydrogen production via algae-biomass co-gasification

Thanadol Tuntiwongwat, Takashi Yukawa, Thongchai Srinophakun, Kanit Manatura, Somboon Sukpancharoen, Seyedali Mirjalili

2025Cleaner Engineering and Technology13 citationsDOIOpen Access PDF

Abstract

The growing demand for sustainable energy has intensified interest in hydrogen (H 2 ) production via biomass co-gasification. This study uniquely integrates thermodynamic modeling with advanced machine learning (ML) techniques to optimize H 2 production and syngas quality from algae-biomass blends—a novel approach that addresses critical gaps in renewable energy production. Three algae species (Chlorella vulgaris, Nannochloropsis oculata, and Fucus serratus) were co-gasified with three biomass types (Fir Pellet (FP), Palm Empty Fruit Bunch (PEFB), and Pellet Pine Wood (PPW)) using a comprehensive Aspen Plus® simulation framework based on Gibbs free energy minimization. Unlike previous research that typically relies on either simulation or experimental methods in isolation, our approach combines Aspen Plus® simulations with six distinct ML algorithms to create a comprehensive predictive framework. Simulations identified optimal conditions, including a gasification temperature (GT) of 800°C and an equivalence ratio (ER) of 0.1–0.5, achieving energy and exergy efficiencies of 87.73% and 84.79%, respectively. The innovative incorporation of algae significantly enhanced H 2 yield and syngas quality, leveraging algae's high reactivity and sustainability benefits. Six ML models—namely Extreme Gradient Boosting (XGB), Random Forest (RF), Support Vector Regression (SVR), K-Nearest Neighbors (KNN), Decision Tree (DT), and Artificial Neural Networks (ANN)—were applied to predict H 2 yield and syngas lower heating value (LHV). XGB demonstrated unprecedented predictive accuracy for H 2 yield, with an R 2 exceeding 0.98 and RMSE of 0.220, while RF excelled in LHV predictions, achieving an R 2 of 0.951 and RMSE of 0.452. This study is the first to identify and quantify the significance of key operational parameters (GT, steam-to-fuel ratio (S/F), ER, and blend in feed (%) (BF (%))) through Shapley additive explanations (SHAP), establishing a novel methodology for optimizing renewable H 2 production that can be adapted across various feedstock combinations, advancing the field of sustainable energy systems.

Topics & Concepts

Hydrogen productionBiomass (ecology)Biomass gasificationAlgaeProduction (economics)HydrogenEnvironmental scienceProcess engineeringChemistryEcologyEngineeringBiologyEconomicsOrganic chemistryMacroeconomicsThermochemical Biomass Conversion ProcessesSubcritical and Supercritical Water ProcessesCatalysis and Hydrodesulfurization Studies
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