Synthesis and activation of phase-pure and defect-free metal–organic frameworks (MOFs) are essential for establishing accurate structure–property relationships.
We report the syntheses, structures, and oxidation catalytic activities of a single-atom-based vanadium oxide incorporated in two highly crystalline MOFs, Hf-MOF-808 and Zr-NU-1000. These vanadium catalysts were introduced by a postsynthetic metalation, and the resulting materials (Hf-MOF-808-V and Zr-NU-1000-V) were thoroughly characterized through a combination of analytic and spectroscopic techniques including single-crystal X-ray crystallography. Their catalytic properties were investigated using the oxidation of 4-methoxybenzyl alcohol under an oxygen atmosphere as a model reaction. Crystallographic and variable-temperature spectroscopic studies revealed that the incorporated vanadium in Hf-MOF-808-V changes position with heat, which led to improved catalytic activity.
Electrical conductivity is engendered in a pyrene containing hexa-zirconium(iv) metal–organic framework by physically encapsulating fullerenes within MOF cavity.
Nickel(IV) bis(dicarbollide) is incorporated in a zirconium-based metal-organic framework (MOF), NU-1000, to create an electrically conductive MOF with mesoporosity. All the nickel bis(dicarbollide) units are located as guest molecules in the microporous channels of NU-1000, which permits the further incorporation of other active species in the remaining mesopores. For demonstration, manganese oxide is installed on the nodes of the electrically conductive MOF. The electrochemically addressable fraction and specific capacitance of the manganese oxide in the conductive framework are more than 10 times higher than those of the manganese oxide in the parent MOF.
The understanding of the catalyst−support interactions has been an important challenge in heterogeneous catalysis since the supports can play a vital role in controlling the properties of the active species and hence their catalytic performance. Herein, a series of isostructural mesoporous metal−organic frameworks (MOFs) based on transition metals, lanthanides, and actinides (Zr, Hf, Ce, Th) were investigated as supports for a vanadium catalyst. The vanadium species was coordinated to the oxo groups of the MOF node in a single-ion fashion, as determined by single-crystal X-ray diffraction, diffuse reflectance infrared Fourier transform spectroscopy, and diffuse reflectance UV−vis spectroscopy. The support effects of these isostructural MOFs were then probed using the aerobic oxidation of 4-methoxybenzyl alcohol as a model reaction. The turnover frequency was found to be correlated with the electronegativity and oxidation state of the metal cations on the supporting MOF nodes, highlighting an important consideration when designing catalyst supports.
Zr-based metal-organic frameworks (MOFs) have been known for their excellent stability; however, due to the high connectivity of the Zr nodes, it is challenging to introduce flexibility into Zr-MOFs. Here we present a flexible Zr-MOF named NU-1400 comprising 4-connected Zr nodes and tetratopic linkers. It exhibits guest-dependent structural flexibility with up to 48% contraction in the unit cell volume as evidenced by single-crystal X-ray diffraction studies. The expanded or contracted conformations of NU-1400 showed drastically different reactivity toward the hydrolysis of a nerve agent simulant owing to the size-selective effect toward the reactant.
Uremic toxins often accumulate in patients with compromised kidney function, like those with chronic kidney disease (CKD), leading to major clinical complications including serious illness and death. Sufficient removal of these toxins from the blood increases the efficacy of hemodialysis, as well as the survival rate, in CKD patients. Understanding the interactions between an adsorbent and the uremic toxins is critical for designing effective materials to remove these toxic compounds. Herein, we study the adsorption behavior of the uremic toxins, p-cresyl sulfate, indoxyl sulfate, and hippuric acid, in a series of zirconium-based metal−organic frameworks (MOFs). The pyrene-based MOF, NU-1000, offers the highest toxin removal efficiency of all the MOFs in this study. Other Zr-based MOFs possessing comparable surface areas and pore sizes to NU-1000 while lacking an extended aromatic system have much lower toxin removal efficiency. From single-crystal X-ray diffraction analyses assisted by density functional theory calculations, we determined that the high adsorption capacity of NU-1000 can be attributed to the highly hydrophobic adsorption sites sandwiched by two pyrene linkers and the hydroxyls and water molecules on the Zr 6 nodes, which are capable of hydrogen bonding with polar functional groups of guest molecules. Further, NU-1000 almost completely removes p-cresyl sulfate from human serum albumin, a protein that these uremic toxins bind to in the body. These results offer design principles for potential MOFs candidates for uremic toxin removal.
The
Zr6-based metal–organic framework NU-1000
was successfully functionalized with candidate catalystsMoS
x
unitsvia SIM (solvothermal deposition
in MOFs) of molybdenum(VI), followed by reaction with H2S gas. The structure of the material, named MoS
x
-SIM, was characterized
spectroscopically and through a single-crystal X-ray diffraction measurement.
These measurements and others established that the catalyst is monometallic,
with mixed oxygen and sulfur coordination, and that it forms from
a MOF-node-supported molybdenum-based cluster featuring only oxy ligands.
Notably, the formal potential for the MOF-grafted complex, like that
for the metal–sulfur active site of hydrogenase, is nearly
coincident with the formal potential for the hydrogen couple. Its
effective concentration within the mesoporous MOF is several hundred
millimolar, and its porous-framework-based immobilization/heterogenization
obviates the need for aqueous solubility as a condition for use as
a well-defined catalyst. MoS
x
-SIM was evaluated as an electrocatalyst
for evolution of molecular hydrogen from aqueous acid. Although the
MoS
x
-functionalized framework exhibits
catalytic behavior, the highly insulating nature of the support inhibits
high electrocatalytic performance. Introduction of an archetypal redox
mediator (RM), methyl viologen (MV2+), resulted in more
than 20-fold enhancement in its catalytic performance on a turnover
frequency basis, implying efficient RM-assisted electron transfer
to otherwise electrochemically non-addressable MoS
x
moieties. Electrochemical kinetic studies with additional
viologens as mediators reveal an unexpected square-root dependence
of overall reaction rate on mediator concentration, as well as sensitivity
to the strength of RM•+ as a reductant. These observations,
together with observations of potential-dependent H/D isotope effects
and potential-dependent pH effects, provide useful insights into the
catalysis mechanism and help to explain how the MOF-affixed monometallic
catalyst can effectively catalyze a two-electron reduction reaction,
i.e., hydrogen evolution from acidified water.
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