Synthesis pathway and combustion mechanism of a sustainable biofuel 2,5-Dimethylfuran: Progress and prospective

•Synthesis pathway of DMF through catalyst reactions was thoroughly reviewed.•The oxidation and pyrolysis mechanism of DMF were critically analyzed.•Laminar burning velocity and flame instability were discussed in detail.•Ignition delay times and spray characteristics were comprehensively evaluated....

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Veröffentlicht in:	Fuel (Guildford) 2021-02, Vol.286, p.119337, Article 119337
Hauptverfasser:	Tuan Hoang, Anh, Nižetić, Sandro, Ölçer, Aykut I., Chyuan Ong, Hwai
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Sprache:	eng
Schlagworte:	2,5-Dimethylfuran Alternative fuel Biodiesel fuels Biofuels Biomass burning Catalyst synthesis Catalysts Combustion Commercialization Decomposition Decomposition mechanism Decomposition reactions Emission analysis Flame characteristics Fossil fuels Lignocellulose Model accuracy Motivation Oxidation Pyrolysis Quantum chemistry Spray characteristics Synthesis
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description	•Synthesis pathway of DMF through catalyst reactions was thoroughly reviewed.•The oxidation and pyrolysis mechanism of DMF were critically analyzed.•Laminar burning velocity and flame instability were discussed in detail.•Ignition delay times and spray characteristics were comprehensively evaluated. In recent years, 2,5-Dimethylfuran (DMF) is found as a promising new biofuel generation that could be synthesized from renewable and available lignocellulosic biomass in small-to-large scale. The combustion characteristics of DMF are believed to be comparable to those of fossil fuels. Many studies have focused on the synthesis pathways of DMF from the various feedstock, while decomposition mechanism and combustion characteristics were also carefully investigated by experiments and simulations. In addition, kinetic mechanisms were developed in detail and were used to compare to quantum chemical calculations. However, the production strategy should be understood clearly to target the commercialization goal of DMF. Moreover, the decomposition mechanism through pyrolysis and oxidation reactions, flame characteristics, and spray characteristics of DMF should be completely analyzed to evaluate the characteristics of combustion and emission formation as applying DMF to the engine. In the current paper, the production progress of DMF was thoroughly detailed via catalyst reactions. More importantly, the critical route from decomposition to combustion was critically discussed based on the collection and consolidation of data achieved from experiment and the kinetic model validations aiming to improve the data fidelity, to develop the accuracy of kinetic models, and to minimize the experimental uncertainties. Finally, this work could become a motivation to perform further investigations on using DMF as a promising biofuel for the engine.
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In recent years, 2,5-Dimethylfuran (DMF) is found as a promising new biofuel generation that could be synthesized from renewable and available lignocellulosic biomass in small-to-large scale. The combustion characteristics of DMF are believed to be comparable to those of fossil fuels. Many studies have focused on the synthesis pathways of DMF from the various feedstock, while decomposition mechanism and combustion characteristics were also carefully investigated by experiments and simulations. In addition, kinetic mechanisms were developed in detail and were used to compare to quantum chemical calculations. However, the production strategy should be understood clearly to target the commercialization goal of DMF. Moreover, the decomposition mechanism through pyrolysis and oxidation reactions, flame characteristics, and spray characteristics of DMF should be completely analyzed to evaluate the characteristics of combustion and emission formation as applying DMF to the engine. In the current paper, the production progress of DMF was thoroughly detailed via catalyst reactions. More importantly, the critical route from decomposition to combustion was critically discussed based on the collection and consolidation of data achieved from experiment and the kinetic model validations aiming to improve the data fidelity, to develop the accuracy of kinetic models, and to minimize the experimental uncertainties. 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subjects	2,5-Dimethylfuran Alternative fuel Biodiesel fuels Biofuels Biomass burning Catalyst synthesis Catalysts Combustion Commercialization Decomposition Decomposition mechanism Decomposition reactions Emission analysis Flame characteristics Fossil fuels Lignocellulose Model accuracy Motivation Oxidation Pyrolysis Quantum chemistry Spray characteristics Synthesis
title	Synthesis pathway and combustion mechanism of a sustainable biofuel 2,5-Dimethylfuran: Progress and prospective
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