Stabilization of Dinuclear Rhodium and Iridium Clusters on Layered Titanate and Niobate Supports

Stabilization of Dinuclear Rhodium and Iridium Clusters on Layered Titanate and Niobate Supports

Atomically dispersed organometallic clusters can provide well-defined nuclearity of active sites for both fundamental studies as well as new regimes of activity and selectivity in chemical transformations. More recently, dinuclear clusters adsorbed onto solid surfaces have shown novel catalytic prop...

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Veröffentlicht in:Inorganic chemistry 2022-11, Vol.62 (3)
Hauptverfasser: Uppuluri, Ritesh, Hwang, Sooyeon, Maheshwari, Sharad, Zhao, Pengwei, Gray, Jennifer L., Rosas, Alyssa S., Yennawar, Hemant P., Fan, Xiaobin, Janik, Michael J., Mallouk, Thomas E.
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bimetallic clusters
INORGANIC, ORGANIC, PHYSICAL, AND ANALYTICAL CHEMISTRY
nanosheets
scanning transmission electron microscopy
single atom catalysis
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container_issue 3
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container_title Inorganic chemistry
container_volume 62
creator Uppuluri, Ritesh
Hwang, Sooyeon
Maheshwari, Sharad
Zhao, Pengwei
Gray, Jennifer L.
Rosas, Alyssa S.
Yennawar, Hemant P.
Fan, Xiaobin
Janik, Michael J.
Mallouk, Thomas E.
description Atomically dispersed organometallic clusters can provide well-defined nuclearity of active sites for both fundamental studies as well as new regimes of activity and selectivity in chemical transformations. More recently, dinuclear clusters adsorbed onto solid surfaces have shown novel catalytic properties resulting from the synergistic effect of two metal centers to anchor different reactant species. Difficulty in synthesizing, stabilizing, and characterizing isolated atoms and clusters without agglomeration challenges allocating catalytic performance to atomic structure. Here, we explore the stability of dinuclear rhodium and iridium clusters adsorbed onto layered titanate and niobate supports using molecular precursors. Both systems maintain their nuclearity when Statistical analysis of HAADF-STEM images revealed that rhodium and iridium dimers had mean cluster-to-cluster distances very similar to what is expected from a random distribution of atoms over a large area, indicating that they are dispersed without aggregation. The stability of dinuclear rhodium clusters supported on titanate nanosheets was also investigated by X-ray absorption fine structure (EXAFS), DRIFTS, and first-principles calculations. Both X-ray absorption spectroscopy and HAADF-STEM simulations, guided by density functional theory (DFT)-optimized structure models, suggested that rhodium dimers adsorb onto the nanosheets in an end-on binding mode that is stable up to 100 degrees C under reducing conditions. Finally, this study highlights that crystalline nanosheets derived from layered metal oxides can be used as model supports to selectively stabilize dinuclear clusters, which could have implications for heterogeneous catalysis.
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The stability of dinuclear rhodium clusters supported on titanate nanosheets was also investigated by X-ray absorption fine structure (EXAFS), DRIFTS, and first-principles calculations. Both X-ray absorption spectroscopy and HAADF-STEM simulations, guided by density functional theory (DFT)-optimized structure models, suggested that rhodium dimers adsorb onto the nanosheets in an end-on binding mode that is stable up to 100 degrees C under reducing conditions. 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INORGANIC, ORGANIC, PHYSICAL, AND ANALYTICAL CHEMISTRY
nanosheets
scanning transmission electron microscopy
single atom catalysis
title Stabilization of Dinuclear Rhodium and Iridium Clusters on Layered Titanate and Niobate Supports
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