Advancement in utilization of nanomaterials as efficient and recyclable solid catalyst for biodiesel synthesis

Shamim Islam , Bidangshri Basumatary , Samuel Lalthazuala Rokhum , Prince Kumar Mochahari , Sanjay Basumatary
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引用次数: 3

Abstract

Energy consumption is increasing day by day, thereby depleting the fossil fuel reserve at an alarming rate. The fossil-based fuels have many adverse effects on the environment and cause global warming due to emission of greenhouse gases. Biodiesel produced via the transesterification process is an alternative, eco-friendly, and renewable fuel. Transesterification is carried out using homogeneous, enzyme, and heterogeneous catalysts. Heterogeneous catalysts can resolve the issues faced by the homogeneous and enzyme catalysts during biodiesel synthesis. At the same time, heterogeneous nanocatalysts have much more potential due to their higher surface area, more selectivity, and stronger catalytic activity. In this review, various nanocatalysts such as metal oxides (CaO, MgO, ZnO, Ti2O, CuO, and ZrO2), magnetic nanocatalyst, nano-zeolite catalyst, and nano-hydrotalcite catalysts were studied. In addition, catalyst preparation methods, physical properties of catalyst along with various reaction parameters such as reaction temperature and time, methanol to oil molar ratio (MTOMR), catalyst loading, and biodiesel yield were highlighted and discussed. In short, biodiesel synthesis using nanocatalyst can provide a cheap and clean energy and thus the nanocatalyst can be further developed as a strong candidate for the global energy industry in the future.

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纳米材料作为高效可回收固体催化剂在生物柴油合成中的应用进展
能源消耗日益增加,从而以惊人的速度消耗化石燃料储备。化石燃料对环境有许多不利影响,由于排放温室气体导致全球变暖。通过酯交换过程生产的生物柴油是一种可替代的、环保的和可再生的燃料。酯交换反应可使用均相、酶和非均相催化剂进行。多相催化剂可以解决均相催化剂和酶催化剂在生物柴油合成过程中所面临的问题。同时,非均相纳米催化剂由于具有更大的表面积、更高的选择性和更强的催化活性而具有更大的应用潜力。本文综述了金属氧化物(CaO、MgO、ZnO、Ti2O、CuO、ZrO2)、磁性纳米催化剂、纳米沸石催化剂、纳米水滑石催化剂等纳米催化剂的研究进展。此外,还重点讨论了催化剂的制备方法、催化剂的物理性质以及反应温度和时间、甲醇油摩尔比(MTOMR)、催化剂负载和生物柴油产率等各种反应参数。总之,利用纳米催化剂合成生物柴油可以提供一种廉价和清洁的能源,因此纳米催化剂可以进一步发展,成为未来全球能源工业的有力候选。
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