SYNTHESIS OF NICKEL BASED CORE-SHELL CATALYST AND CHARACTERIZATION FOR DRY REFORMING OF METHANE PROCESS
Dry reforming of methane reaction is a reaction between CO2 and CH4 to produce synthesis gas (CO and H2). This reaction requires a very high temperature around 800oC for the reaction to take place and results in high conversion. The catalyst commonly used for this reaction is a catalyst with nick...
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| Format: | Final Project |
| Language: | Indonesia |
| Online Access: | https://digilib.itb.ac.id/gdl/view/48695 |
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| Institution: | Institut Teknologi Bandung |
| Language: | Indonesia |
| Summary: | Dry reforming of methane reaction is a reaction between CO2 and CH4 to produce synthesis
gas (CO and H2). This reaction requires a very high temperature around 800oC for the
reaction to take place and results in high conversion. The catalyst commonly used for this
reaction is a catalyst with nickel as the active site, one of which is the Ni/Al2O3 catalyst. The
disadvantage of commercial catalysts that are commonly used is the deactivation of catalysts
due to the phenomenon of sintering caused by the high operating temperature needed in the
reaction. Choosing the right catalyst to use can minimize catalyst deactivation and can
improve catalyst performance. The latest technology in making catalysts for the dry
reforming of methane reaction is in the form of core-shell NiO@Al2O3 which can prevent the
catalyst from deactivating the catalyst.
This study aims to synthesize and characterize the NiO@Al2O3 catalyst for the dry reforming
of methane reaction. Synthesis of catalyst was carried out using the microemulsion method.
Variations made in this study are variations in the composition of nickel of 77% -wt, 64% wt,
and 52% -wt with variations in calcination temperature carried out at 600oC, 700oC and
800oC. This study compared the effect of nickel and alumina composition and catalyst
calcination temperature on crystallinity, surface area, pore size distribution, and catalyst
morphology. Characterization was performed using the XRF, XRD, HRTEM, BET, and BJH
tests.
The results showed that the average crystallite size of the NiO@Al2O3 catalyst produced is in
the range of 9-13 nm, surface area is in the range of 73 –171 m2/g, and pore diameters of 10-
22 nm. The synthesized NiO@Al2O3 catalyst has the form of multiple small core-shell coated
by a single shell material with NiO particle size less than 20 nm. The core-shell structure
obtained is able to inhibit the increase in Ni grain size (sintering) effectively at high
temperatures compared to NiO/Al2O3 impregnation catalysts. |
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