Abstract
Research on single-atom catalysts (SACs), or atomically dispersed catalysts, has been quickly gaining momentum over the past few years. Although the unique electronic structure of singly dispersed atoms enables uncommon-sometimes exceptional-activities and selectivities for various catalytic applications, developing reliable and general procedures for preparing stable, active SACs in particular for applications under reductive conditions remains a major issue. Herein, the challenges associated with the synthesis of SACs are highlighted semiquantitatively and three stabilization techniques inspired by colloidal science including steric, ligand, and electrostatic stabilization are proposed. Some recent examples are discussed in detail to showcase the power of these strategies in the synthesis of stable SACs without compromising catalytic activity. The substantial further potential of steric, ligand, and electrostatic effects for developing SACs is emphasized. A perspective is given to point out opportunities and remaining obstacles, with special attention given to electrostatic stabilization where little is done so far. The stabilization strategies presented herein have a wide applicability in the synthesis of a series of new SACs with improved performances.
Highlights
A significant portion of noble metals produced on earth are used as supported catalysts, including 40.0% Pt, 79.5% Pd and 80.9% Rh.[1]
The immobilization of positively charged species on inorganic supports can be achieved at relatively high weight loadings,[6] those isolated metal species tend to aggregate under reductive conditions and the synthesis of stable and active Single-atom catalysts (SACs) remains a considerable challenge for reactions under non-oxidative conditions
Future perspective & concluding remarks Future research should be devoted to developing more methodologies that are reliable and reproducible for the synthesis of a broad range of single atom catalysts based on various metal atoms and supports
Summary
A significant portion of noble metals produced on earth are used as supported catalysts, including 40.0% Pt, 79.5% Pd and 80.9% Rh.[1].
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