catalysts produced nearly 100% conv

catalysts produced nearly 100% conversion with product selectivity
reaching 90%. The catalysts were stable for 10 h with negligible
coke deposition. Therefore, although catalyst regeneration strategies
are available for restoring the activity of coked catalyst,
preventing the deactivation in situ will be more economical for the
industry. The enhanced activity and stability properties demonstrated
by the metals and phosphorous modifiers present an
alternative for improving the prospects of the overall process.
However, further studies are still essential to fully establish the
most appropriate modifier loading suitable for commercial
applications and the applicable reaction conditions.
Recent HDO and HDC studies with other transition metals
A summary of some recent studies on the behaviors of the
transition metals-based catalysts during the hydroprocessing of
some vegetable oils under variable conditions has also been
presented in Table 2 [76–83]. In all the cases, the reactions proceed
via the HDO/HDC mechanism, with the side reactions being mainly
of methanation and water-gas types. The main reaction products
were n- and i-alkanes with carbon chains in the range of C7 to C18
(i.e. potentials for biojet fuels). Among these, the higher alkanes
(i.e. C16 to C18) could be successfully cracked to lighter liquid
alkanes with 15 or less-carbon numbers over hydrocracking
catalysts like the acidic zeolites prior to hydroisomerization. It
could be established that, catalytic activity was dependent on
several factors that include the nature of the catalyst, operation
conditions, nature of the support, metal loading and in some
instances the incorporation of a second or third metal. According to
Srifa and co-workers [76], increasing the hydrogen/oil ratio from
1000 to 2000 led to the formation of mainly liquid alkanes (i.e.
selectivity increased from 0 to 100%). At the lower ratio of 1000,
only solid alkanes were produced (28%). These compounds can
however be converted into the C5 to C15 alkanes by hydrocracking
with zeolite catalysts. NiMo catalysts supported with Al2O3 have
generally demonstrated good activity toward alkanes’ production,
with limited degree of side reactions than supported CoMo
catalysts. Modification of Al2O3 with B2O3 may have a negative
effect on the alkanes yield. Similarly, SiO2 being less acidic was
more favorable to production of alkanes than H-Y for the Ni2P
catalyst under constant conditions. According to Zarchin et al. [77],
with 25 wt.% Ni2P/SiO2, the soybean oil yields 84% of desired
alkanes compared to 78% obtained with 25 wt.% Ni2P/H-Y catalyst.
Promotion of Ni with Mo or W produces a comparable activity
under constant conditions. Modification of NiMo/Al2O3 system
with 1–25 wt.% of Ce showed slight modification to the hydrotreating
properties of jatropha oil. At both low and high loadings
(i.e. 1–25 wt.%), the selectivity to alkanes was in the range of 89–
91% [82]. Lowering the reaction temperature from 320 to 280 8C
had a positive effect on the production of alkanes from palm oil
using 7 wt.%Ni/SAPO-11 catalyst. It could be seen that, the
selectivity increased from 44 to 79% when the temperature was
reduced from 320 to 280 8C [83]. A similar trend could be observed
by increasing the loading of Ni particles. When the loading was
increased from 2 to 7 and 9 wt.%, the selectivity to alkanes
increased from 60 to 67 and 68%, respectively [79].
Catalyst deactivation during HDO/HDC of vegetable oils
Catalyst deactivation involved the decay of catalytic performance
(i.e. activity) or the associated reduction in selectivity to
desired reaction products over time. The mode of the deactivation
process is usually dependent on the reaction being carried out.
Catalyst replacement usually posed a great challenge to refineries
due to the costs involved. Therefore, understanding the processes
of catalyst deactivation and the appropriate strategies for
mitigating the catalyst deactivation would be very beneficial for
the industry. Several catalysts deactivation routes are known.
These include fouling (i.e. the deposition of materials like coke that
cover the catalyst active sites), poisoning by the interaction of
catalyst with poisons such as gases, water, metals, etc. in the
reaction stream or produced during the reaction, catalyst
decomposition by heat (i.e. thermal degradation) and agglomeration
of the active catalyst particles by sintering process (i.e.
crystallite growth).
Catalyst deactivation during HDO/HDC of vegetable oils depend
on the nature of the catalyst and the compositions of the vegetable
oil feedstock. Noble metal catalysts are associated with low
thermal stability and could therefore be sintered at elevated
temperatures. At reaction temperatures reaching 500 8C, active Pd
or Pt particles could be sintered by agglomeration (i.e. crystallite
growth) [37]. This reduces accessibility be reactants due to the
reduction in the active catalyst surface area with a consequent
reduction in the yields of hydrocarbon products (particularly the
C5 to C15 alkanes required for jet fuels). The hydrodeoxygenation
(HDO), in particular, produces water molecules that can destroy
active noble metal catalyst sites by poisoning due to high
sensitivity to poisons of these catalysts [38]. Catalyst containing
sulfur such as CoMoS are more susceptible to deactivation by
impurities like fatty acids and lipid-based impurities or water in
the vegetable oil feeds [59]. These impurities strongly interact with
active CoMoS catalyst sites and caused poisoning with a great
negative consequence of lowering catalytic activity. Therefore,
reaction with refined vegetable oils would be a very good
alternative. Another problem with sulfur-containing catalysts is
the removal of the sulfur species at high temperature via
hydrogenation (i.e. interaction of catalyst with hydrogen employed
for the reaction). The H2S produced under this condition can also
serve as a catalyst poison. The poisoning normally occurs through
the strong interaction of these impurities. This trigger active sites
blockage, destroy geometric catalyst structure and consequently
cause activity loss. The reaction selectivity is usually shifted