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Enhanced CO2 methanation at mild temperature on Ni/zeolite from kaolin: effect of metal–support interface

Novia Amalia Sholeha, Novia Amalia Sholeha and Mohamad, Surahim and Bahruji, Hasliza and Prasetyoko, Didik and Nurul Widiastuti, Nurul Widiastuti and Abdul Fatah, Nor Aiza and Abdul Jalil, Aishah and Taufiq Yap, Yun Hin (2021) Enhanced CO2 methanation at mild temperature on Ni/zeolite from kaolin: effect of metal–support interface. RSC Advances, 11 (27). pp. 16376-16387. ISSN 2046-2069

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Official URL: http://dx.doi.org/10.1039/d1ra01014j

Abstract

Catalytic CO2 hydrogenation to CH4 offers a viable route for CO2 conversion into carbon feedstock. The research aimed to enhance CO2 conversion at low temperature and to increase the stability of Ni catalysts using zeolite as a support. NaZSM-5 (MFI), NaA (LTA), NaY (FAU), and NaBEA (BEA) synthesized from kaolin were impregnated with 15% Ni nanoparticles in order to elucidate the effect of surface area, porosity and basicity of the zeolite in increasing Ni activity at mild temperature of ~200 °C. A highly dispersed Ni catalyst was produced on high surface area NaY meanwhile the mesoporosity of ZSM-5 has no significant effect in improving Ni dispersion. However, the important role of zeolite mesoporosity was observed on the stability of the catalyst. Premature deactivation of Ni/NaA within 10 h was due to the relatively small micropore size that restricted the CO2 diffusion, meanwhile Ni/NaZSM-5 with a large mesopore size exhibited catalytic stability for 40 h of reaction. Zeolite NaY enhanced Ni activity at 200 °C to give 21% conversion with 100% CH4 selectivity. In situ FTIR analysis showed the formation of hydrogen carbonate species and formate intermediates at low temperatures on Ni/NaY, which implied the efficiency of electron transfer from the basic sites of NaY during CO2 reduction. The combination of Ni/NaY interfacial interaction and NaY surface basicity promoted CO2 methanation reaction at low temperature.

Item Type:Article
Uncontrolled Keywords:CO2 conversion, catalytic stability
Subjects:T Technology > TP Chemical technology
Divisions:Chemical and Energy Engineering
ID Code:95544
Deposited By: Widya Wahid
Deposited On:31 May 2022 12:46
Last Modified:31 May 2022 12:46

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