Active-Site-Accessible, Porphyrinic Metal−Organic Framework Materials

Abstract

On account of their structural similarity to cofactors found in many metallo-enzymes, metalloporphyrins are obvious potential building blocks for catalytically active, metal−organic framework (MOF) materials. While numerous porphyrin-based MOFs have already been described, versions featuring highly accessible active sites and permanent microporosity are remarkably scarce. Indeed, of the more than 70 previously reported porphyrinic MOFs, <i>only one</i> has been shown to be both permanently microporous and contain internally accessible active sites for chemical catalysis. Attempts to generalize the design approach used in this single successful case have failed. Reported here, however, is the synthesis of an extended family of MOFs that directly incorporate a variety of metalloporphyrins (specifically Al³⁺, Zn²⁺, Pd²⁺, Mn³⁺, and Fe³⁺ complexes). These <b>r</b>obust <b>p</b>orphyrinic <b>m</b>aterials (<b>RPM</b>s) feature large channels and readily accessible active sites. As an illustrative example, one of the manganese-containing <b>RPM</b>s is shown to be catalytically competent for the oxidation of alkenes and alkanes.