高温氧化中的单中心催化与簇催化

Single-Site vs. Cluster Catalysis in High Temperature Oxidations.

作者信息

Serna Pedro, Rodríguez-Fernández Aida, Yacob Sara, Kliewer Christine, Moliner Manuel, Corma Avelino

机构信息

ExxonMobil Research and Engineering Co., Corporate Strategic Research, Annandale, NJ, 08801, USA.

Instituto de Tecnología Química, Universitat Politècnica de València-Consejo Superior de Investigaciones Cientificas (UPV-CSIC), Av. de los Naranjos, s/n, 46022, Valencia, Spain.

出版信息

Angew Chem Int Ed Engl. 2021 Jul 12;60(29):15954-15962. doi: 10.1002/anie.202102339. Epub 2021 Jun 9.

DOI:10.1002/anie.202102339

PMID:33881798

Abstract

The behavior of single Pt atoms and small Pt clusters was investigated for high-temperature oxidations. The high stability of these molecular sites in CHA is a key to intrinsic structure-performance descriptions of elemental steps such as O dissociation, and subsequent oxidation catalysis. Subtle changes in the atomic structure of Pt are responsible for drastic changes in performance driven by specific gas/metal/support interactions. Whereas single Pt atoms and Pt clusters (> ca. 1 nm) are unable to activate, scramble, and desorb two O molecules at moderate T (200 °C), clusters <1 nm do so catalytically, but undergo oxidative fragmentation. Oxidation of alkanes at high T is attributed to stable single Pt atoms, and the C-H cleavage is inferred to be rate-determining and less sensitive to changes in metal nuclearity compared to its effect on O scrambling. In contrast, when combustion involves CO, catalysis is dominated by metal clusters, not single Pt atoms.

摘要

研究了单个铂原子和小铂簇在高温氧化中的行为。这些分子位点在CHA中的高稳定性是对诸如氧解离等基本步骤以及后续氧化催化进行本征结构-性能描述的关键。铂原子结构的细微变化是由特定气体/金属/载体相互作用驱动的性能急剧变化的原因。虽然单个铂原子和大于约1 nm的铂簇在中等温度（200 °C）下无法活化、争夺和解吸两个氧分子，但小于1 nm的簇能催化进行此过程，但会发生氧化碎片化。高温下烷烃的氧化归因于稳定的单个铂原子，并且推断C-H裂解是速率决定步骤，与它对氧争夺的影响相比，对金属核数变化不太敏感。相比之下，当燃烧涉及CO时，催化作用由金属簇主导，而非单个铂原子。

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高温氧化中的单中心催化与簇催化

Single-Site vs. Cluster Catalysis in High Temperature Oxidations.

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