利用半灌木废种子油生物质生产生物能源:减少环境污染的战略

Rozina , Okezie Emmanuel , Mushtaq Ahmad , Thaddeus C. Ezeji , Nasib Qureshi , Sheikh Zain Ul Abidin
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摘要

从非食用油和废油中提取的生物柴油为柴油发动机提供了一种更清洁、更可持续的替代燃料来源。本研究利用金盏花水叶提取物合成的氧化碲纳米粒子,探讨了将非食用冲天香树种子油转化为环保生物柴油的潜力。利用先进技术对催化剂进行了表征,发现其晶体结构,颗粒平均直径为 45 纳米。值得注意的是,在特定的反应条件下:甲醇与油的摩尔比为 8:1、催化剂负载量为 0.62 wt%、反应时间为 120 分钟、温度为 92.5 °C,该催化剂在四个循环中表现出高效的重复利用率,峰值产率达到 93%。核磁共振波谱分析(1H 和 13C NMR)结果证实,非食用种子油成功转化为甲酯。气相色谱-质谱(GC-MS)分析确定 9-十八碳烯酸甲酯为主要脂肪酸甲酯。合成生物柴油的燃料性能符合国际标准,闪点高(98°C),硫含量超低(0.0002%),具有清洁和成本效益高的特点。这项研究为推动生物产品促进可持续生物经济做出了重要贡献,提出了一种同时解决环境和社会经济问题的综合生物能源生产方法。
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Bioenergy production from waste seed oil biomass of Cupressus sempervirens: A strategy for reducing environmental pollution

Biodiesel, derived from non-edible and spent oils, presents a cleaner and more sustainable alternative fuel source for diesel-powered engines. This study investigates the potential of converting non-edible Cupressus sempervirens seed oil into eco-friendly biodiesel using tellurium oxide nanoparticles synthesized with aqueous leaf extract of Calendula arvensis. Advanced techniques were utilized to characterize the catalyst, revealing its crystalline structure, with particles averaging 45 nm. Remarkably, the catalyst demonstrated efficient reusability over four cycles, achieving a peak yield of 93% under specific reaction conditions: a methanol to oil molar ratio of 8:1, a catalyst loading of 0.62 wt%, a reaction time of 120 min, and a temperature of 92.5 °C. Results from nuclear magnetic resonance spectrometry (1H and 13C NMR) confirmed the successful conversion of the non-edible seed oil into methyl ester. Gas chromatography mass spectrometry (GC-MS) analysis identified 9-octadecenoic acid methyl ester as the predominant fatty acid methyl ester. The fuel properties of the synthesized biodiesel met international standards, with a high flash point (98°C), and ultra-low sulfur content of 0.0002%, highlighting its clean and cost-effective nature. This study contributes significantly to advancing bioproducts for a sustainable bioeconomy, presenting an integrated approach to bioenergy production that simultaneously addresses environmental and socio-economic concerns.

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