The limited stocks of fossil fuel a

The limited stocks of fossil fuel and increased environmental awareness have generated a
growing interest in new, renewable energy sources [1, 2]. Biomass is an important source of
renewable energy for the future. In 2003, biomass contributed nearly 2.9 quadrillion BTUs
(quads) to USA’s energy supply, nearly 3 % of the total US energy consumption of about 98quads. Biomass, which comprises 47 % of the total renewable energy consumption, is the
single largest renewable energy resource currently being used [3–5]. Recently, bio-oil
obtained from fast pyrolysis of biomass is widely gaining attention as a potential candidate
for future liquid fuels [6]. Fast pyrolysis is a thermochemical process in which biomass is
heated rapidly to 350–600 °C in the absence of oxygen to produce bio-oil [7]. Fast pyrolysis
process is influenced by a lot of factors such as feedstock type, feedstock size, treatment
before pyrolysis, and pyrolysis process conditions. Bio-oil with high yield and good quality
can be obtained by optimizing these factors [8].
Any form of biomass, such as wood, agricultural waste, grasses, and forestry residues,
can be a feedstock for fast pyrolysis [9–13]. In our recent work, pinewood was used as the
feedstock to study the effect of pretreatment on the pyrolysis bio-oil. The results showed that
bio-oil characteristics and yield were influenced by pretreatment methods. Pinewood pretreated
with 1 and 0.5 % H2SO4 produced bio-oils with the highest yield, 63 %, compared to 54, 44,
and 49% yields for untreated, steam explosion, and alkaline treatments, respectively. Chemical
characterization showed that the quality of bio-oil obtained from 1 % H2SO4 pretreatment was
the best because of a low water content of 27.45 %, high pH of 2.77, high viscosity of 7.31 cSt,
and a heating value of 16.53 MJ/kg. The lowest bio-oil yield of 49% was obtained from alkalipretreated
pinewood, which was attributed to the increased ash content in alkali-pretreated
material [14]. In this work, alkali pretreatment was not attempted because of the poor results
observed for pinewood.
This study is an extension of our work on pinewood. In the current work, we evaluated
the effect of pretreatment on bio-oil production from other feedstocks such as sweetgum,
switchgrass, and corn stover. Sweetgum is a hardwood feedstock and has spread distribution
throughout the southeast USA. Although it is not commercially used in logging, it has
potential as a sustainable biomass and can be used in biochemical or thermochemical
conversion to biofuels [15, 16]. Switchgrass is a perennial grass and grown throughout
North America mainly as a forage crop or as ground cover to control erosion. Its rapid
growth rate and winter hardiness make it an attractive biomass crop for biofuel production.
The crop can be used to produce ethanol by fermentation or bio-oil by pyrolysis [17]. Corn
stover is the most plentiful agricultural residue produced in the USA. A 2005 study
estimated that 75 million dry tons (DT) of corn stover per year could be harvested in USA
[18]. The study also estimated that with moderate to high yield increases harvested, corn
stover could soar to between 170 and 256 million DT per year by 2030. Thus, corn stover is
considered to have major potential as an energy feedstock.
The objective of the present study was to investigate the effect of acid, steam explosion,
and size reduction pretreatments on bio-oil yield and characteristics from the following three
feedstocks: sweetgum, switchgrass, and corn stover.