posted on 2016-02-22, 05:20authored byAnil Baral, Bhavik R. Bakshi, Raymond
L. Smith
Recognizing the contributions of ecosystem services and
the lack
of their comprehensive accounting in life cycle assessment (LCA),
an in-depth analysis of their contribution in the life cycle of cellulosic
ethanol derived from five different feedstocks was conducted, with
gasoline and corn ethanol as reference fuels. The relative use intensity
of natural resources encompassing land and ecosystem goods and services
by cellulosic ethanol was estimated using the Eco-LCA framework. Despite
being resource intensive compared to gasoline, cellulosic ethanol
offers the possibility of a reduction in crude oil consumption by
as much as 96%. Soil erosion and land area requirements can be sources
of concern for cellulosic ethanol derived directly from managed agriculture.
The analysis of two broad types of thermodynamic metrics, namely:
various types of physical return on investment and a renewability
index, which indicate competitiveness and sustainability of cellulosic
ethanol, respectively, show that only ethanol from waste resources
combines a favorable thermodynamic return on investment with a higher
renewability index. However, the production potential of ethanol from
waste resources is limited. This finding conveys a possible dilemma
of biofuels: combining high renewability, high thermodynamic return
on investment, and large production capacity may remain elusive. A
plot of renewability versus energy return on investment is suggested
as one of the options for providing guidance on future biofuel selection.