Biobutanol Recovery Using Nonfluorinated Task-Specific Ionic Liquids

Biobutanol has received major attention as an alternative for and additive to fossil fuels. Biobutanol produced via fermentation is hampered by low butanol concentrations in the fermentation broth. An efficient separation process is required to make biobutanol production economically viable. In this...

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Veröffentlicht in:	Industrial & engineering chemistry research 2012-06, Vol.51 (24), p.8293-8301
Hauptverfasser:	Garcia-Chavez, Lesly Y, Garsia, Christian M, Schuur, Boelo, de Haan, André B
Format:	Artikel
Sprache:	eng
Schlagworte:	Applied sciences Butanol Chemical engineering Coefficients Distillation Economics Exact sciences and technology Fermentation Ionic liquids Liquid-liquid extraction Solvents
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container_title	Industrial & engineering chemistry research
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creator	Garcia-Chavez, Lesly Y Garsia, Christian M Schuur, Boelo de Haan, André B
description	Biobutanol has received major attention as an alternative for and additive to fossil fuels. Biobutanol produced via fermentation is hampered by low butanol concentrations in the fermentation broth. An efficient separation process is required to make biobutanol production economically viable. In this work, liquid–liquid extraction of butanol from water, employing nonfluorinated task-specific ionic liquids (TSILs) has been evaluated against distillation and extraction with conventional solvents. Experimental data for the equilibrium distribution ratios of butanol and water were used in a conceptual process design study to find the most promising solvent. The results show that the IL with the best distribution coefficient and very high selectivity was [TOAMNaph] (D BuOH = 21, S = 274), performing much better than the benchmark solvent oleyl alcohol (D BuOH = 3.42, S = 192). The conceptual design study showed that butanol extraction with [TOAMNaph] requires 73% less energy than in conventional distillation (5.65 MJ/kg BuOH vs 21.3 MJ/kg for distillation).
doi_str_mv	10.1021/ie201855h
format	Article
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subjects	Applied sciences Butanol Chemical engineering Coefficients Distillation Economics Exact sciences and technology Fermentation Ionic liquids Liquid-liquid extraction Solvents
title	Biobutanol Recovery Using Nonfluorinated Task-Specific Ionic Liquids
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