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  • Perspective
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Fuels and energy carriers from single-site catalysts prepared via surface organometallic chemistry

Abstract

The petrochemical industry relies on catalysts for hydrocarbon conversions that often contain ill-defined active metal sites, hampering rational improvement. Surface organometallic chemistry (SOMC) has enabled the design of catalysts with tailored metal sites, often referred to as single sites. In this Perspective, I consider how SOMC has opened routes to synthesis of fuels and energy carriers not possible via traditional approaches and led to the discovery of alkane homologation processes, by giving access to a large proportion of low coordinated and highly reactive surface sites. While challenges lie ahead, particularly with respect to the improvement of catalyst activity and lifetime, as well as further control and characterization of active/surface site structure, SOMC is effective for increasing molecular level understanding of catalytic events as found in related industrial systems. Furthermore, single-site catalysts can also be used to provide molecular level precision in complex systems such as supported nanoparticles where dopant and support effects are ubiquitous, but poorly understood.

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Fig. 1: Conversion of methane to valuable intermediates and energy carriers.
Fig. 2: Alkane dehydrogenation.
Fig. 3: Alkane homologation processes and catalysts.
Fig. 4: Proposed active sites in non-oxidative methane coupling catalysts.
Fig. 5: Methane to methanol conversion process.

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Copéret, C. Fuels and energy carriers from single-site catalysts prepared via surface organometallic chemistry. Nat Energy 4, 1018–1024 (2019). https://doi.org/10.1038/s41560-019-0491-2

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