Extraction of Furfural and Furfural/5-Hydroxymethylfurfural from Mixed Lignocellulosic Biomass-Derived Feedstocks

We present a combined in silico and experimental study on the extraction of furfural and 5-hydroxymethylfurfural (HMF) in aqueous-organic biphasic systems. We predict the liquid-liquid equilibria and furfural/HMF partition coefficients of over 2200 water-organic biphasic systems using the multiscale COSMO-RS model and measure experimentally single-component (furfural) and mixture (furfural and HMF) partition coefficients at room and dehydration reaction-relevant temperatures in 28 solvents. We find the experimental data to be within a factor of 2 from the COSMO-RS predictions. Even though furfural and HMF have chemical similarity, the slight differences in molecular structure render the separation of furfural easier by the supply of more solvents of higher partition coefficient for extraction. We leverage this molecular difference and experimentally demonstrate that with an additional extraction step, using dichloromethane or toluene, we can selectively extract furfural from furfural-HMF mixtures, which can coexist in lignocellulosic biomass dehydration products, despite their partition coefficients being generally correlated. We complement solvent selection criteria for biphasic lignocellulosic biomass processes with a simple mass balance extraction model for determining volume ratios in multistage extraction. Finally, the molecular nature of the preferential furfural extraction is rationalized using COSMO-RS sigma-profile analysis.

Automated summary

In this study, a combined in silico and experimental approach was used to investigate the extraction of furfural and HMF in aqueous-organic biphasic systems. The experimental data were found to be in good agreement with the predictions from the COSMO-RS model, and a selective extraction of furfural was demonstrated using an additional extraction step. The molecular nature of preferential furfural extraction was rationalized using COSMO-RS sigma-profile analysis.