Life cycle assessment of ethanol produced in a biorefinery from liquid hot water pretreated switchgrass

Life cycle assessments of fuel bioethanol produced in Uruguay from liquid hot water pretreated switchgrass were performed for two scenarios: the production of ethanol and electricity and a biorefinery producing ethanol, electricity, furfural, acetic, and formic acid. Experimental data and material and energy balances derived from the simulations were used to analyze the global warming potential of fuel bioethanol. Greenhouse gas (GHG) emissions in both scenarios were lower than the reference emissions for fossil fuel. The biorefinery scenario had a better performance in terms of environmental impacts, and the biofuel produced met GHG reduction requirements. Switchgrass composition, enzyme dosage, fermentation and hydrolysis efficiency, and solids content had a significant effect on environmental performance, with enzyme use being the most significant factor. A multi-objective optimization was used to find the values of solid content and enzyme dose that minimize GHG emissions and the minimum ethanol selling price (MESP). An enzyme dosage of 37 mg(protein)/g(glucan) and solids content of 21% w/w were the optimal conditions for bioethanol production with an associated GHG value of 2 +/- 5 g CO2 eq./MJ(ethanol) and a MESP of $0.84/L. (C) 2021 Elsevier Ltd. All rights reserved.

Automated summary

Life cycle assessments were conducted on fuel bioethanol produced in Uruguay from liquid hot water pretreated switchgrass for two scenarios: ethanol and electricity production, and a biorefinery producing various chemicals. Results showed that the biorefinery scenario had lower greenhouse gas emissions compared to fossil fuels and met GHG reduction requirements. Factors such as switchgrass composition, enzyme dosage, fermentation efficiency, and solids content significantly impacted environmental performance, with enzyme use being the most significant.