Recently, vegetable oil fuels are b

Recently, vegetable oil fuels are becoming more attractive because
of their renewability, energy security and due to their
high-energy content which is close to that of petroleum based fuels
[7–9]. The properties of biodiesel are similar to that of regular diesel
fuel, and can be used as a fuel blend or as a substitute for diesel
fuel [6,10,11]. Nowadays different vegetable oils such as soybean,
rapeseed, camelina, palm, and sunflower oils are being used for
the production of biodiesel. Among all the potential oil sources
for the production of biodiesel, palm is one of the most abundant
oils in the world with a high yield of 4.2 tons ha1 year1 and is
economical [12,13]. Palm oil accounts for one third of the total
oil production in the world, and requires a very small land area
compared to that of other oil crops [14]. Several methods like dilution
[15], microemulsions [16], pyrolysis [17], catalytic cracking
[18] and transesterification [16,19] can be employed to produce
biodiesel from vegetable oils. Out of all the conversion processes,
transesterification is the most economical and simplest way to produce
biodiesel [3,20]. This process provides a fuel with physical
characteristics close to that of regular diesel fuel, with little or no
deposits when used in diesel engines [5,20]. Transesterification is
a process in which the triglycerides present in the vegetable oils
chemically react with alcohol to produce alkyl esters and glycerol
with the aid of catalyst. Based on the type of catalyst used in the
transesterification, this process was categorized into alkali, acid
and enzyme catalytic processes. The alkali process gives a high
purity and high yield of biodiesel in a short span of reaction time
but is not suitable for oils with high free fatty acid (FFA) content
[21]. For such kinds of oils acid esterification followed by alkali
transesterification can be employed to reduce the high FFA content
and to improve the biodiesel yield [9]. However, the longer reaction
time and low catalyst recovery are problems with this process
[22]. Enzyme catalytic transesterification requires longer reaction
times [16]. To overcome these limitations, Saka and Demirbas proposed
a different route to produce biodiesel from vegetable oil. In
this process biodiesel can be produced via non-catalytic transesterification
under supercritical alcohol conditions [23,24].