Polyoxometalates
(POMs) featuring 7, 12, 18, or more redox-accessible
transition metal ions are ubiquitous as selective catalysts, especially
for oxidation reactions. The corresponding synthetic and catalytic
chemistry of stable, discrete, capping-ligand-free polythiometalates
(PTMs), which could be especially attractive for reduction reactions,
is much less well developed. Among the challenges are the propensity
of PTMs to agglomerate and the tendency for agglomeration to block
reactant access of catalyst active sites. Nevertheless, the pervasive
presence of transition metal sulfur clusters metalloenzymes or cofactors
that catalyze reduction reactions and the justifiable proliferation
of studies of two-dimensional (2D) metal-chalcogenides as reduction
catalysts point to the promise of well-defined and controllable PTMs
as reduction catalysts. Here, we report the fabrication of agglomeration-immune,
reactant-accessible, capping-ligand-free CoIIMo6
IVS24
n– clusters
as periodic arrays in a water-stable, hierarchically porous Zr-metal–organic
framework (MOF; NU1K) by first installing a disk-like Anderson polyoxometalate,
CoIIIMo6
VIO24
m–, in size-matched micropores where the siting
is established via difference electron density (DED) X-ray diffraction
(XRD) experiments. Flowing H2S, while heating, reduces
molybdenum(VI) ions to Mo(IV) and quantitatively replaces oxygen anions
with sulfur anions (S2–, HS–,
S2
2–). DED maps show that MOF-templated
POM-to-PTM conversion leaves clusters individually isolated in open-channel-connected
micropores. The structure of the immobilized cluster as determined,
in part, by X-ray photoelectron spectroscopy (XPS), X-ray absorption
fine structure (XAFS) analysis, and pair distribution function (PDF)
analysis of total X-ray scattering agrees well with the theoretically
simulated structure. PTM@MOF displays both electrocatalytic and photocatalytic
competency for hydrogen evolution. Nevertheless, the initially installed
PTM appears to be a precatalyst, gaining competency only after the
loss of ∼3 to 6 sulfurs and exposure to hydride-forming metal
ions.
