Low-oxygenated biofuels production from palm oil through hydrocracking process using the enhanced Spent RFCC catalysts

Utilization of the enhanced Spent Residue Fluid Catalytic Cracking (SRFCC) catalysts through the acid treatment was conducted for the palm oil hydrocracking process to produce biofuels. The catalysts were characterized using Pyridine-probed Fourier Transform Infrared (Pyridine-FTIR) spectroscopy and...

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Bibliographic Details
Published in:Bioresource technology reports 2021-06, Vol.14, p.100677, Article 100677
Main Authors: Istadi, I., Riyanto, Teguh, Khofiyanida, Elok, Buchori, Luqman, Anggoro, Didi D., Sumantri, Indro, Putro, Bagus H.S., Firnanda, Agyet S.
Format: Article
Language:English
Subjects:
Brønsted acid site
Deoxygenation
Hydrocracking
Lewis acid site
Palm oil
RFCC catalysts
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Summary:Utilization of the enhanced Spent Residue Fluid Catalytic Cracking (SRFCC) catalysts through the acid treatment was conducted for the palm oil hydrocracking process to produce biofuels. The catalysts were characterized using Pyridine-probed Fourier Transform Infrared (Pyridine-FTIR) spectroscopy and Brunauer−Emmett−Teller-Barrett−Joyner−Halenda (BET-BJH) method. The higher number of Brønsted acid sites on the enhanced SRFCC catalysts leads to the lower conversion of palm oil as well as lower deoxygenation activity because of the slower carbocations formation process as the initiation reaction. On the other hand, the Lewis acid sites on the enhanced SRFCC catalysts have a significant role in the deoxygenation reaction mechanism. Meanwhile, the catalysts surface area and pore size are responsible for tailoring the diffusion mechanism of the mass transfer process of reactant molecules. The introduction of hydrogen gas in the reaction system has a significant role in deoxygenation, double bond cleavage, and de-coking process mechanisms. [Display omitted] •Hydrocracking conversion of palm oil into biofuels using acid-base catalysts•Enhanced Spent Residue Fluid Catalytic Cracking (RFCC) catalysts for hydrocracking•Brønsted acid sites on the RFCC catalysts lead to the lower conversion of palm oil.•Lewis acid site on the RFCC catalysts leads to the deoxygenation reaction mechanism.•Hydrocracking system tailors the deoxygenation and double bond cleavage.
ISSN:2589-014X
2589-014X
DOI:10.1016/j.biteb.2021.100677