Sebastian Grundner scite author profile

Copper-exchanged zeolites with mordenite structure mimic the nuclearity and reactivity of active sites in particulate methane monooxygenase, which are enzymes able to selectively oxidize methane to methanol. Here we show that the mordenite micropores provide a perfect confined environment for the highly selective stabilization of trinuclear copper-oxo clusters that exhibit a high reactivity towards activation of carbon–hydrogen bonds in methane and its subsequent transformation to methanol. The similarity with the enzymatic systems is also implied from the similarity of the reversible rearrangements of the trinuclear clusters occurring during the selective transformations of methane along the reaction path towards methanol, in both the enzyme system and copper-exchanged mordenite.

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Synthesis of single-site copper catalysts for methane partial oxidation

Grundner

et al. 2016

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Formation of Active Cu-oxo Clusters for Methane Oxidation in Cu-Exchanged Mordenite

et al. 2019

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Cu-exchanged zeolites are known to be active in the selective oxidation of methane to methanol at moderate temperatures. Among them, Cu-exchanged mordenite (MOR) is the system that has so far shown the highest methanol yield per Cu atom. This high efficiency is attributed to the ability of MOR to selectively stabilize an active tricopper cluster with a [Cu3(μ-O)3]2+ structure when activated in the presence of O2 at high temperatures. In this study, we investigate the elementary steps in the formation of [Cu3(μ-O)3]2+ by in situ X-ray absorption spectroscopy and ultraviolet–visible spectroscopy. We demonstrate that the Cu cations undergo a series of thermally driven steps during activation that precede the formation of the active oxidizing species. We hypothesize that the thermal formation of highly mobile Cu+ species by autoreduction of Cu2+ in an inert gas is essential to enable the reorganization of Cu ions in MOR, which is necessary for the formation of a reduced precursor of [Cu3(μ-O)3]2+. Such a precursor can be oxidized in the presence of strong oxidantssuch as O2 and N2Oto form active [Cu3(μ-O)3]2+ at temperatures as low as 50 °C.

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