Kinetic and thermodynamic of heterogeneously K3PO4/AC-catalysed transesterification via pseudo-first order mechanism and Eyring-Polanyi equation

Kinetic and thermodynamic of heterogeneously K3PO4/AC-catalysed transesterification via pseudo-first order mechanism and Eyring-Polanyi equation

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The use of carbon-based catalysts has drawn so much interest in biodiesel production due to improved reaction performance. However, there was lack of comprehensive studies in term of its kinetic and thermodynamic perspective. Therefore, a methodical study is essential to uncover the influence of the...

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Bibliographic Details
Main Authors: Ali, AAM (Author), Farid, MAA (Author), Hasan, MY (Author), Hassan, MA (Author), Ibrahim, ML (Author), Othman, MR (Author), Shirai, Y (Author), Taufiq-Yap, YH (Author)
Format: Article
Language:English
Published: 2018
Subjects:
ACTIVATED CARBON
Biodiesel
BIODIESEL PRODUCTION
Carbon-based catalyst
CATALYSTS
Eyring-Polanyi equation
FATTY-ACIDS
FEEDSTOCKS
Heterogeneous reaction
JATROPHA OIL
Kinetic and thermodynamic
NANOCATALYSTS
Pseudo-first order
WASTE COOKING OIL
Online Access:View Fulltext in Publisher
Description
Summary:The use of carbon-based catalysts has drawn so much interest in biodiesel production due to improved reaction performance. However, there was lack of comprehensive studies in term of its kinetic and thermodynamic perspective. Therefore, a methodical study is essential to uncover the influence of the carbon catalyst with respect to reaction rate and yield. This study represents kinetic and thermodynamic of heterogeneously K3PO4/AC-catalysed transesterification. It was done correspondingly via pseudo-first order mechanism and Eyring-Polanyi equation, whereby, under the optimal reaction temperature of 333.15 K, all data have fitted satisfactorily in both models with resulted R-2 of 0.99, respectively. Activation energy (E-a) and Gibbs free energy (Delta G) were calculated as 34.2 kJ mol(-1) and -33.68 kJ mol(-1), indicating the reaction was exergonic and spontaneous at high temperature.
DOI:10.1016/j.fuel.2018.06.029

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