Citation
Santo, Istiyak Amin and Lim, Siow Chun and Lee, It Ee and Tan, Wooi Haw and Ho, Chai Yee and Razali, Nur Mazlini and Yusoff, Lukeman (2026) Tri-objective co-optimization of waste-cooking-oil biodiesel using machine learning, NSGA-II, and life-cycle assessment. Energy Reports, 15. p. 108907. ISSN 23524847|
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Tri-objective co-optimization of waste-cooking-oil biodiesel using machine learning, NSGA-II, and life-cycle assessment.pdf - Published Version Restricted to Repository staff only Download (3MB) |
Abstract
Turning waste cooking oil (WCO) into biodiesel reduces waste and fossil fuel dependence, yet performance and environmental impacts are typically assessed in isolation, obscuring critical trade-offs. We identify operating conditions that simultaneously maximize biodiesel yield, increase higher heating value (HHV), and minimize process energy per kilogram of fuel. Using 500 designed experiments varying seven factors ( methanol-to-oil ratio, catalyst loading, temperature, reaction time, mixing speed, free fatty acid content, and water content). We train multiple machine learning models and apply multi-objective optimization. XGBoost delivers the best predictive accuracy across all targets; SVR performs worst for HHV. A gate-to-gate life cycle assessment (per 1 kg biodiesel) quantifies environmental impacts. The optimizer yields 58 Pareto-optimal solutions; a balanced point achieves 85.9 wt% yield, 38.2 MJ kg−1 HHV, and 5.1 MJ kg−1 process energy. Compared to a conventional baseline, this solution reduces global warming potential, acidification, and eutrophication by 11.3% on average. Unlike sequential approaches that optimize performance first and assess sustainability afterward, our integrated ML–optimization–LCA framework unifies prediction, search, and environmental evaluation in a single workflow, explicitly revealing trade-offs among yield, fuel quality, and energy intensity. This enables producers to select operating points aligned with priorities – higher output, better fuel, or lower energy – while quantifying environmental co-benefits. Policymakers can leverage these insights to align biodiesel production with carbon reduction and efficiency targets, supporting cleaner, scalable deployment at plant scale
| Item Type: | Article |
|---|---|
| Uncontrolled Keywords: | Biodiesel |
| Subjects: | T Technology > TP Chemical technology > TP315-360 Fuel |
| Divisions: | Faculty of Artificial Intelligence & Engineering (FAIE) |
| Depositing User: | Ms Rosnani Abd Wahab |
| Date Deposited: | 02 Mar 2026 00:17 |
| Last Modified: | 02 Mar 2026 00:17 |
| URII: | http://shdl.mmu.edu.my/id/eprint/15376 |
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