Kinetic Control via Binding Sites within the Confined Space of Metal Metalloporphyrin‐Frameworks for Enhanced Shape‐Selectivity Catalysis

Author:

Zhang Weijie1,Lu Zhou1,Wojtas Lukasz2,Chen Yu‐Sheng3,Baker Alexander A.4,Liu Yi‐Sheng5,Al‐Enizi Abdullah M.6,Nafady Ayman6,Ma Shengqian1ORCID

Affiliation:

1. Department of Chemistry University of North Texas Denton TX-76203 USA

2. Department of Chemistry University of South Florida Tampa FL-33620 USA

3. ChemMatCARS Center for Advanced Radiation Sources The University of Chicago Argonne IL-60439 USA

4. Lawrence Livermore National Laboratory Livermore CA-94550 USA

5. Advanced Light Source Lawrence Berkeley National Laboratory Berkeley CA-94720 USA

6. Department of Chemistry College of Science King Saud University Riyadh 11451 Saudi Arabia

Abstract

AbstractOne striking feature of enzyme is its controllable ability to trap substrates via synergistic or cooperative binding in the enzymatic pocket, which renders the shape‐selectivity of product by the confined spatial environment. The success of shape‐selective catalysis relies on the ability of enzyme to tune the thermodynamics and kinetics for chemical reactions. In emulation of enzyme's ability, we showcase herein a targeting strategy with the substrate being anchored on the internal pore wall of metal‐organic frameworks (MOFs), taking full advantage of the sterically kinetic control to achieve shape‐selectivity for the reactions. For this purpose, a series of binding site‐accessible metal metalloporphyrin‐frameworks (MMPFs) have been investigated to shed light on the nature of enzyme‐mimic catalysis. They exhibit a different density of binding sites that are well arranged into the nanospace with corresponding distances of opposite binding sites. Such a structural specificity results in a facile switch in selectivity from an exclusive formation of the thermodynamically stable product to the kinetic product. Thus, the proposed targeting strategy, based on the combination of porous materials and binding events, paves a new way to develop highly efficient heterogeneous catalysts for shifting selectivity.

Funder

Welch Foundation

Basic Energy Sciences

Division of Chemistry

King Saud University

Fuel Cell Technologies Program

Hydrogen and Fuel Cell Technologies Office

Publisher

Wiley

Subject

General Chemistry,Catalysis

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