The stability of Pd/TS-1 and Pd/silicalite-1 for catalytic oxidation of methane – understanding the role of titanium

Hosseiniamoli, Hadi; Setiawan, Adi; Adesina, Adesoji A.; Kennedy, Eric M.; Stockenhuber, Michael

Title: The stability of Pd/TS-1 and Pd/silicalite-1 for catalytic oxidation of methane – understanding the role of titanium
Creator: Hosseiniamoli, Hadi; Setiawan, Adi; Adesina, Adesoji A.; Kennedy, Eric M.; Stockenhuber, Michael
Relation: Catalysis Science and Technology Vol. 10, Issue 4, p. 1193-1204
Publisher Link: http://dx.doi.org/10.1039/c9cy01579e
Publisher: Royal Society of Chemistry
Resource Type: journal article
Date: 2020
Description: The stability of Pd/TS-1 and Pd/silicalite-1 catalysts was assessed at 400 °C and an approximate relative humidity (RH) of 80% for catalytic combustion of fugitive methane emissions at low concentrations, aiming to understand the role of titanium in the stability of the catalysts. The long-term stability of both catalysts is attributed to both hydrophobicity and low acidity of aluminium-free zeolites. The structure and bonding of Pd deposited on the TS-1 catalyst were fully evaluated using a number of techniques including EXAFS, XPS and TEM. Pd/silicalite-1, in contrast to Pd supported on TS-1, displayed a gradual deactivation over 30 h time-on-stream. This deactivation occurred coincident with the agglomeration of palladium atoms on the surface of this catalyst as well as carbon deposition, whereas this phenomenon was not observed for the Pd/TS-1 material. It is concluded that the hydrophobicity and low acidity is the reason for the high stability and activity of Pd supported on TS-1. In contrast, the dispersion of palladium in Pd/silicalite-1 (and indeed Pd on alumina) decreased remarkably and carbon deposits were formed on the catalyst, contributing to the deactivation. We showed by both, Ti K and Pd K EXAFS analysis an anchoring role of Ti for Pd and confirmed the location of the Pd active in the combustion. It is suggested that the Ti in the T positions of the TS-1 framework forms the sites for palladium particles at an average distance of 2.5 Å and inhibits the sintering of palladium particles. In contrast to acidic supports, we did not observe deactivation by deposition of carbon containing species. Hence, the notable stability of Pd/TS-1 over 1900 h of reaction results in Pd/TS-1 being the most promising catalyst for methane combustion in industrial applications.
Subject: titanium; palladium particles; methane combustion; catalyst stability
Identifier: http://hdl.handle.net/1959.13/1439377
Identifier: uon:40905
Identifier: ISSN:2044-4753
Language: eng
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