Environmental, Economic, and Scalability Considerations of Selected Bio-Derived Blendstocks for Mixing-Controlled Compression Ignition Engines

Abstract: Economic and environmental favorability are vital considerations for the large-scale development and deployment of sustainable fuels. Here, we have conducted economic and sustainability analyses of pathways for producing bioblendstocks optimized for improved combustion for mixing-controlled compression ignition (MCCI) engines. We assessed 25 pathways for the production of target fuels from renewable feedstocks and conducted technoeconomic analysis (TEA) and life cycle analysis (LCA) to determine which bioblend… Show more

“…The impact of avoided methane emissions is dramatic, as this gas traps heat more than 20 times as efficiently as CO 2 ; 31 these avoided emissions are credited as negative CO 2 -eq emissions in accordance with previous work. 2 , 29 Biogenic credits for the VFA upgrading pathways were between 69 and 73 g CO 2 -eq./MJ which were very similar to the combustion emissions during vehicle or jet fuel used for each product (70–75 g CO 2 -eq./MJ), offsetting these emissions. These emissions are accordingly omitted from Figure 7 , unlike those of the petrofuels.…”

“…Conversion of wet waste-derived VFAs to fuels also avoids methane emissions which would otherwise result from traditional waste management options such as landfilling of organic wet wastes, giving these processes low to negative life cycle carbon emissions; this is crucial as methane is more than 20 times as efficient at trapping atmospheric heat as CO 2 . 2 , 3 , 17 , 28 , 29 , 30 , 31 Alcohols and alkanes formed by these upgrading processes are promising blendstocks 18 for end fuel uses including gasoline, jet, or diesel. We approximate upgrading processes and blending capacity of upgraded molecules in petrofuels using a MATLAB script, the VFA Upgrading to Liquid Transportation fUels Refinery Estimation (VULTURE), written for this work.…”

Screening and evaluation of biomass upgrading strategies for sustainable transportation fuel production with biomass-derived volatile fatty acids

“…The impact of avoided methane emissions is dramatic, as this gas traps heat more than 20 times as efficiently as CO 2 ; 31 these avoided emissions are credited as negative CO 2 -eq emissions in accordance with previous work. 2 , 29 Biogenic credits for the VFA upgrading pathways were between 69 and 73 g CO 2 -eq./MJ which were very similar to the combustion emissions during vehicle or jet fuel used for each product (70–75 g CO 2 -eq./MJ), offsetting these emissions. These emissions are accordingly omitted from Figure 7 , unlike those of the petrofuels.…”

“…Conversion of wet waste-derived VFAs to fuels also avoids methane emissions which would otherwise result from traditional waste management options such as landfilling of organic wet wastes, giving these processes low to negative life cycle carbon emissions; this is crucial as methane is more than 20 times as efficient at trapping atmospheric heat as CO 2 . 2 , 3 , 17 , 28 , 29 , 30 , 31 Alcohols and alkanes formed by these upgrading processes are promising blendstocks 18 for end fuel uses including gasoline, jet, or diesel. We approximate upgrading processes and blending capacity of upgraded molecules in petrofuels using a MATLAB script, the VFA Upgrading to Liquid Transportation fUels Refinery Estimation (VULTURE), written for this work.…”

Screening and evaluation of biomass upgrading strategies for sustainable transportation fuel production with biomass-derived volatile fatty acids

“…However, the furan mixtures and prenol–isoprenol mixture were categorized as unknown. As discussed by Kolodziej and Scheib, blending isobutanol with gasoline (up to 12.5 vol%) produces a similar gasoline at 2.7% O 2 content, which is acceptable by engine manufacturers; therefore, the U.S. EPA waiver (211b) could potentially allow isobutanol blending levels up to 16.1%, which produces a final fuel with the same oxygen content (3.5%) and heating value as an ethanol 10% blend (E10) . Finally, there are legal restrictions for blending these fuels such as limits on oxygenates (1-butanol, isopropanol, isobutanol, prenol, propanol/ethanol mixture) and olefins (prenol, diisobutylene).…”

Identification of Key Drivers of Cost and Environmental Impact for Biomass-Derived Fuel for Advanced Multimode Engines Based on Techno-Economic and Life Cycle Analysis

“…Since the interest on lignin as an alternative to fossil-fuels based technologies has gained considerable attention recently, lignin-only LCA studies have emerged, which are either focused on lignin extraction [289][290][291][292][293][294][295][296][297][298][299] or lignin-based products (asphalt, [300][301][302][303][304] adhesives, [305][306][307] resins, 308 fine chemicals, [309][310][311][312][313][314] carbon fibres 315 and fuels. 287,[316][317][318][319][320] Lignin as a product from biorefineries is a new concept, therefore most of the LCA conducted are based on either well quantified extraction processes such as Kraft or based on experimental lab scale data which has been extrapolated. In the latest case, the LCA allows to evaluate the environmental impact of an upscaled biorefinery.…”

“…However, lignin is considered only as energy cogeneration in this study. 320 The LCA on bio-jet fuel from poplar biomass was performed by Budsberg et al 318 This study uses lignin as a source of H 2 using hog fuel as the alternative energy source.…”

Lignin for energy applications – state of the art, life cycle, technoeconomic analysis and future trends