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Carbon footprint and fossil energy consumption of bio-ethanol fuel production from Arundo donax L. crops on marginal lands of Southern Italy

TitleCarbon footprint and fossil energy consumption of bio-ethanol fuel production from Arundo donax L. crops on marginal lands of Southern Italy
Publication TypeArticolo su Rivista peer-reviewed
Year of Publication2018
AuthorsForte, A., Zucaro Amalia, Faugno S., Basosi R., and Fierro A.
JournalEnergy
Volume150
Pagination222-235
ISSN03605442
KeywordsArundo donax, Bioethanol, biofuel, Campania [Italy], Carbon dioxide, carbon footprint, Crops, Data handling, Digital storage, Emission control, energy conservation, Energy utilization, Environmental impact, Ethanol, Ethanol fuels, Feedstocks, Fossil energy, Fossil energy consumption, gasoline, GHG mitigation, Giant reed, greenhouse gas, Greenhouse gas (GHG), Greenhouse gases, innovation, Innovative technology, Italy, life cycle, life cycle analysis, Lignocellulosic feedstocks, Plants (botany), reedbed, renewable resource, Risk assessment, soil carbon, Spatial and temporal variability, Supply chains
Abstract

A cradle-to-wheel life cycle analysis evaluated the greenhouse gas (GHG) contribution and fossil energy consumption (FEC) of bio-ethanol (EtOH) from dedicated crops on marginal lands in Campania Region (Southern Italy). The analysis processed experimental agronomic data of giant reed cultivated on hilly areas at high erosion risk and industrial data of feedstock conversion to EtOH, through second generation innovative technologies. Two ethanol–gasoline mixes (E10 and E85) were considered and compared with gasoline vehicle (GV). The E10 GHG and FEC profiles were driven by the gasoline input in the blend and the linked CO2 tailpipe emissions. The EtOH supply chain, especially the crop phase, was the major contributor to E85 impacts. The higher amount of biogenic C in E85 determined a marked reduction over GV of both GHG emissions (−60%) and FEC (−65%). The soil carbon storage would save 25 g CO2 eq per MJ; however, the issue is controversial due to the spatial and temporal variability of the process. Based on land availability, E85 contribution to renewables in the regional transport sector would amount to 4% and the blend wall would be far from saturation. A possible mismatch between future flexi-fuel vehicles density and E85 availability should be considered. © 2018 Elsevier Ltd

Notes

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URLhttps://www.scopus.com/inward/record.uri?eid=2-s2.0-85042676684&doi=10.1016%2fj.energy.2018.02.030&partnerID=40&md5=6ba3be8e163579a9bd16a5719d87a8e7
DOI10.1016/j.energy.2018.02.030
Citation KeyForte2018222