The Carbonate-catalyzed Transesterification of Sunflower Oil for Biodiesel Production: in situ Monitoring and Density Functional Theory Calculations

IF 0.8 4区化学 Q4 CHEMISTRY, MULTIDISCIPLINARY

South African Journal of Chemistry-Suid-Afrikaanse Tydskrif Vir Chemie Pub Date : 2021-01-01 DOI:10.17159/0379-4350/2021/v74a8

M. Nyepetsi, F. Mbaiwa, O. Oyetunji, N. Dzade, N. D. de Leeuw

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引用次数: 1

Abstract

ABSTRACT Biodiesel has emerged as a promising alternative fuel to replace dwindling fossil-based resources, particularly in view of its added environmental merit of reducing additional air pollution. Its specific attraction stems from the similarity of its physical properties to fossil fuel-derived diesel. Although the production of biodiesel is a relatively straightforward process, reaction progress monitoring and product analysis require costly specialist equipment, such as gas chromatography and mass spectrome-try. In this study, we investigate the use of pH in monitoring the progress of carbonate-catalyzed transesterification reactions. Specifically, we focus on potassium and sodium carbonates and sunflower oil. Our results are consistent with the results obtained by other studies using different methods of monitoring. To test the generality of the method, pH measurements were also used to monitor the progress of the potassium carbonate transesterification reaction in the presence of added water, glycerol and gamma-valerolactone (GVL). The obtained results are as expected, with a limited amount of water increasing the trans-esterification rate; glycerol slowing the reaction slightly in accord with Le Chatellier's principles; and GVL increasing the rate due to co-solvent effects. Atomic-level insights into the adsorption mechanism of methanol and water on the (001) surfaces of Na2CO3 and K2CO3 catalysts are provided by first-principles DFT calculations, which explain the increase in transesterification reaction rate upon the addition of water. Keywords: Transesterification, pH monitoring, biodiesel , Density Functional Theory ( DFT), co-solvent.

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用于生物柴油生产的碳酸盐催化葵花籽油酯交换反应:原位监测和密度泛函理论计算

生物柴油已成为一种有前途的替代燃料，以取代日益减少的化石资源，特别是考虑到其额外的环境价值，减少额外的空气污染。它的特殊吸引力源于其物理特性与化石燃料衍生柴油的相似性。虽然生产生物柴油是一个相对简单的过程，但反应过程监测和产品分析需要昂贵的专业设备，如气相色谱法和质谱法。在这项研究中，我们研究了pH值在监测碳酸盐催化酯交换反应过程中的应用。具体来说，我们专注于碳酸钾、碳酸钠和葵花籽油。我们的结果与其他使用不同监测方法的研究结果一致。为了测试该方法的普遍性，还使用pH测量来监测在添加水、甘油和γ -戊内酯(GVL)的情况下碳酸钾酯交换反应的进展。所得结果与预期一致，少量的水增加了反式酯化速率;甘油稍微减缓反应，符合勒夏特利耶原理;由于共溶剂的作用，GVL增加了速率。通过第一性原理DFT计算，在原子水平上深入了解了甲醇和水在Na2CO3和K2CO3催化剂(001)表面的吸附机理，这解释了在加入水后酯交换反应速率的增加。关键词:酯交换，pH监测，生物柴油，密度泛函理论，共溶剂

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来源期刊

South African Journal of Chemistry-Suid-Afrikaanse Tydskrif Vir Chemie 化学-化学综合

CiteScore

3.10

自引率

0.00%

发文量

审稿时长

>12 weeks

期刊介绍： Original work in all branches of chemistry is published in the South African Journal of Chemistry. Contributions in English may take the form of papers, short communications, or critical reviews.

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