Journal ArticleDOI
Catalytic dry reforming of methane over high surface area ceria
TLDR
In this article, high surface area ceria (CeO 2) was synthesized by a surfactant-assisted approach, which has useful dry reforming activity for H 2 and CO production under solid oxide fuel cells (SOFCs) conditions.Abstract:
High surface area ceria (CeO 2 (HSA)), synthesized by a surfactant-assisted approach, was found to have useful dry reforming activity for H 2 and CO production under solid oxide fuel cells (SOFCs) conditions. The catalyst provides significantly higher reforming reactivity and excellent resistance toward carbon deposition compared to Ni/Al 2 O 3 and conventional low surface area ceria (CeO 2 (LSA)) under dry reforming conditions. These enhancements are due to the high redox property of CeO 2 (HSA). During the dry reforming process, the redox reactions between the gaseous components in the system and the lattice oxygen (O x ) take place on ceria surface. Among these reactions, the rapid redox reactions of carbon compounds such as CH 4 , and CO with lattice oxygen (CH 4 + O x → CO + H 2 + O x −1 and CO + O x = CO 2 + O x −1 ) can prevent the formation of carbon species from the methane decomposition and Boudard reactions even at low inlet carbon dioxide concentration. In particular, the dry reforming rate over CeO 2 (HSA) is proportional to the methane partial pressure and the operating temperature. Carbon dioxide presents weak positive impact on the methane conversion, whereas both carbon monoxide and hydrogen inhibit the reforming rate. The activation energies and reforming rates under the same methane concentration for CeO 2 toward the dry reforming are almost equal to the steam reforming as previously reported [1–4] . This result suggests the similar reaction mechanisms for both the steam reforming and the dry reforming over CeO 2 ; i.e., the dry reforming rate is governed by the slow reaction of adsorbed methane, or surface hydrocarbon species, with oxygen in CeO 2 , and a rapid gas–solid reaction between CO 2 and CeO 2 to replenish the oxygen.read more
Citations
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Journal ArticleDOI
Influence of Pr and Ce in dry methane reforming catalysts produced from La1-xAxNiO3-δ perovskites
Germán Sierra Gallego,Jaime Andrés Gallego Marín,Catherine Batiot-Dupeyrat,Joël Barrault,Fanor Mondragón +4 more
TL;DR: In this paper, the average diameter of Ni° on the catalysts LaNiO 3, La 0.9 Ce 0.90 Pr 0.1 NiO 3− δ perovskite was evaluated and showed that the high resistance to deactivation is related to the lower Ni° particle size as well as to the redox chemistry of praseodymium oxide Pr 2 O 3, which may become reoxidized by CO 2 during the reforming reaction to produce PrO 2 and CO.
Journal ArticleDOI
Trends in the catalytic reduction of CO2 by hydrogen over supported monometallic and bimetallic catalysts
TL;DR: In this article, the reduction of CO2 by hydrogen has been conducted on supported catalysts in a batch reactor, and the results showed that catalysts synthesized on a reducible support (CeO2) showed higher activity than on an irreducible support (γ-Al2O3).
Journal ArticleDOI
Application of Ceria in CO2 Conversion Catalysis
TL;DR: The growing threat of global climate change has received increasing attention in recent years as discussed by the authors, and the conversion of CO2 to fuels and chemicals is vital for reducing emissions of greenhouse gases and n...
Journal ArticleDOI
Efficient catalytic abatement of greenhouse gases: Methane reforming with CO2 using a novel and thermally stable Rh–CeO2 catalyst
TL;DR: In this article, a 2% Rh-CeO 2 catalyst was synthesized using the hard template method and characterized by means of N 2 adsorption/desorption, XRD and H 2 -TPR methods.
Journal ArticleDOI
Solid Oxide Fuel Cells fuelled with biogas: Potential and constraints
S. Ali Saadabadi,Aditya Thallam Thattai,Liyuan Fan,Ralph E.F. Lindeboom,Henri Spanjers,P.V. Aravind +5 more
TL;DR: In this article, the advantages and challenges of integrated AD-Solid Oxide Fuel Cell (SOFC) systems against the most recent scientific and practical developments in the AD and SOFC domain are discussed.
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