Synthesis of hierarchical nanozeolites beta and ZSM-5 for green diesel production via hydrodeoxygenation
The application of the conventional zeolites has been limited due to its large crystal size (micrometer) and also due to the microporosity (size < 2nm). Hence, this study has been conducted to produce enhanced nanozeolites to overcome the above mentioned limitations. Herein, two microporous na...
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| Format: | Thesis |
| Language: | English |
| Published: |
2018
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| Subjects: | |
| Online Access: | http://psasir.upm.edu.my/id/eprint/83691/1/FS%202019%2031%20-%20ir.pdf http://psasir.upm.edu.my/id/eprint/83691/ |
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| Summary: | The application of the conventional zeolites has been limited due to its large
crystal size (micrometer) and also due to the microporosity (size < 2nm). Hence,
this study has been conducted to produce enhanced nanozeolites to overcome
the above mentioned limitations. Herein, two microporous nanozeolites namely
Beta and ZSM-5 were synthesized via hydrothermal method. Moreover, the
enhanced hierarchical nanozeolites have been produced via a green
solvothermal approach with the following attributes such as narrow particle size
distribution and appropriate mesopores. The synthesis was based on reducing
the growth of zeolite crystals by surface silanization of zeolitic seeds using
organosilane (hexadecyltrimethoxysilane) as a growth inhibitor. The activities of
these nanozeolites and hierarchical nanozeolites were evaluated with catalytic
hydroprocessing of oleic acid to green diesel by incorporating Ni metals on these
supports. Moreover, extensive characterizations and initial rate investigation
were conducted to determine the nature of acid sites and their structuralfunctional
relationship in selective hydrodeoxygenation (HDO) of octanoic acid.
The results showed hydrothermally synthesized nanozeolites were made of
globular aggregates with broader particle size distributions (48-1273 nm for
zeolite Beta) and (60-135 nm for zeolite ZSM-5). A much smaller and narrower
distributions of globular aggregates of hierarchical nanozeolites are formed
using solvothermal approach with sizes of 65–120 nm (for Beta using acetone)
and 30-100 nm (for ZSM-5 using 1-decanol). These globular aggregates are
actually made by quite smaller primary nanounits ranging 4–11 nm size. The
hierarchical nanozeolites exhibited secondary porosity, especially larger
mesopores found in zeolite Beta (with pore diameter 8.1 nm) due to efficient
functionalization of HDTM in polar solvent environment (acetone). Whereas,
moderate mesopores observed in zeolite ZSM-5 (with pore diameter 7.8 nm)
caused by the alkoxylation of alcohol based solvent (1-decanol). Catalytic hydroprocessing of oleic acid pointed out higher yields of 60% (consisting of
straight and isomeric alkanes C18 and C17) obtained over the microporous
nanozeolites than hierarchical nanozeolites at 350 ◦C and 50 bar pressure. This
is due to high surface activities demonstrated by the larger external surface
areas of microporous nanozeolites. In contrast, the recyclability test of catalysts
revealed that hierarchical nanozeolites minimized catalyst deactivation as they
were capable of retaining their activities, over 40% (for HZSM-5) and 20% (for
HBEA) yields even regenerated after four cycles. As for the initial rate study, all
the Ni/zeolite catalysts exhibited higher selectivity towards the octane over the
heptane, indicating conversion of octanoic acid occurred preferably via HDO
than decarbonylation (DCN) route. The selectivity of the HDO pathway was
strongly influence by the Bronsted acid sites of the zeolites. The initial rate
studies revealed small Ni metal particles and it’s highly dispersibility over support
facilitate high initial catalytic activity. The fatty acid substrate can be
quantitatively hydrodeoxgenated to alkanes by cascade reaction on bifunctional
catalysts based on Ni and an acidic zeolite. The findings of this study discovered
more effective and benign way of producing nanozeolites with high external
surface area and hierarchical porosity that provide remarkable HDO activity and
better catalyst stability as compared to other commercial support catalysts. |
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