Environmentally sustainable production of biodiesel from waste edible oil using Mn–Fe supported magnetic acid heterogeneous catalyst: Optimization via Taguchi L9 technique

IF 5.5 2区化学 Q2 CHEMISTRY, MULTIDISCIPLINARY

Sustainable Chemistry and Pharmacy Pub Date : 2025-04-24 DOI:10.1016/j.scp.2025.102030

Hiarla Cristina Lima dos Santos, Matheus Arrais Gonçalves, Geraldo Narciso da Rocha Filho, Leyvison Rafael Vieira da Conceição

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引用次数: 0

Abstract

The present work reports the synthesis and application of a novel magnetic acid heterogeneous catalyst (MoO₃/MnFe₂O₄) with efficient performance and practical recoverability for biodiesel production from waste cooking oil (WCO). Manganese ferrite (MnFe₂O₄) was successfully prepared via the co-precipitation method to obtain a magnetic support. A molybdenum precursor was added to MnFe₂O₄ by wet impregnation to develop the MoO₃/MnFe₂O₄ catalyst. Surface acidity, XRD, FTIR, SEM, EDS, and VSM were used to characterize the synthesized materials. The MoO₃/MnFe₂O₄ catalyst was evaluated in the transesterification reaction under different operating conditions, including reaction temperature (130.0–170.0 °C), methanol:WCO molar ratio (20:1–40:1), catalyst amount (4.0–8.0 wt%), and reaction time (2.0–4.0 h). An L9 orthogonal array using the Taguchi method was employed to optimize the biodiesel ester content using a minimal number of experimental runs. The mathematical model (R² = 0.932) showed a good correlation between experimental and predicted ester content values. Investigation of the four independent variables revealed temperature as the most significant parameter in biodiesel production using the MoO₃/MnFe₂O₄ catalyst. Under optimal conditions (temperature = 164.5 °C, methanol:WCO molar ratio = 32:1, catalyst amount = 6.5 wt%, and reaction time = 2.5 h), the biodiesel achieved a maximum ester content of 96.7 %, maintaining stable catalytic activity (∼90.0 %) over eight consecutive reaction cycles. This study highlights the importance of fabricating the MoO₃/MnFe₂O₄ catalyst as a new approach to enhancing the biodiesel production process with low energy consumption as well as minimal negative environmental impact.

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锰铁负载磁酸非均相催化剂在废弃食用油中可持续生产生物柴油的研究：田口L9技术优化

本研究报告了一种新型磁性酸性异相催化剂（MoO3/MnFe2O4）的合成和应用，该催化剂具有高效的性能和实用的可回收性，可用于从废弃食用油（WCO）中生产生物柴油。通过共沉淀法成功制备了锰铁氧体（MnFe2O4），从而获得了磁性载体。通过湿法浸渍将钼前驱体添加到 MnFe2O4 中，制备出 MoO3/MnFe2O4 催化剂。利用表面酸度、XRD、FTIR、SEM、EDS 和 VSM 对合成材料进行了表征。在不同的操作条件下，包括反应温度（130.0-170.0 °C）、甲醇与 WCO 摩尔比（20:1-40:1）、催化剂用量（4.0-8.0 wt%）和反应时间（2.0-4.0 h），对 MoO3/MnFe2O4 催化剂进行了酯交换反应评估。采用田口方法的 L9 正交阵列，以最少的实验次数优化生物柴油酯含量。数学模型（R2 = 0.932）显示实验值和预测酯含量值之间具有良好的相关性。对四个自变量的研究表明，温度是使用 MoO3/MnFe2O4 催化剂生产生物柴油的最重要参数。在最佳条件下（温度 = 164.5 °C，甲醇：WCO 摩尔比 = 32:1，催化剂用量 = 6.5 wt%，反应时间 = 2.5 h），生物柴油的酯含量最高可达 96.7%，并在连续八个反应循环中保持稳定的催化活性（∼90.0%）。这项研究强调了制造 MoO3/MnFe2O4 催化剂的重要性，它是提高生物柴油生产工艺的一种新方法，不仅能耗低，而且对环境的负面影响最小。

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来源期刊

Sustainable Chemistry and Pharmacy Environmental Science-Pollution

CiteScore

8.20

自引率

6.70%

发文量

274

审稿时长

37 days

期刊介绍： Sustainable Chemistry and Pharmacy publishes research that is related to chemistry, pharmacy and sustainability science in a forward oriented manner. It provides a unique forum for the publication of innovative research on the intersection and overlap of chemistry and pharmacy on the one hand and sustainability on the other hand. This includes contributions related to increasing sustainability of chemistry and pharmaceutical science and industries itself as well as their products in relation to the contribution of these to sustainability itself. As an interdisciplinary and transdisciplinary journal it addresses all sustainability related issues along the life cycle of chemical and pharmaceutical products form resource related topics until the end of life of products. This includes not only natural science based approaches and issues but also from humanities, social science and economics as far as they are dealing with sustainability related to chemistry and pharmacy. Sustainable Chemistry and Pharmacy aims at bridging between disciplines as well as developing and developed countries.