Ari Turkiewicz scite author profile

Metal-organic frameworks that display step-shaped adsorption profiles arising from discrete pressure-induced phase changes are promising materials for applications in both high-capacity gas storage and energy-efficient gas separations. The thorough investigation of such materials through chemical diversification, gas adsorption measurements, and in situ structural characterization is therefore crucial for broadening their utility. We examine a series of isoreticular, flexible zeolitic imidazolate frameworks (ZIFs) of the type M(bim) 2 (SOD; M = Zn (ZIF-7), Co (ZIF-9), Cd (CdIF-13); bim -= benzimidazolate), and elucidate the effects of metal substitution on the pressure-responsive phase changes and the resulting CO 2 and CH 4 step positions, pre-step uptakes, and step capacities. Using ZIF-7 as a benchmark, we reexamine the poorly understood structural transition responsible for its adsorption steps and, through high-pressure adsorption measurements, verify that it displays a step in its CH 4 adsorption isotherms. The ZIF-9 material is shown to undergo an analogous phase change, yielding adsorption steps for CO 2 and CH 4 with similar profiles and capacities to ZIF-7, but with shifted threshold pressures. Further, the Cd 2+ analogue CdIF-13 is reported here for the first time, and shown to display adsorption behavior distinct from both ZIF-7 and ZIF-9, with negligible pre-step adsorption, a ~50% increase in CO 2 and CH 4 capacity, and dramatically higher threshold adsorption pressures. Remarkably, a single-crystal-to-singlecrystal phase change to a pore-gated phase is also achieved with CdIF-13, providing insight into the phase change that yields step-shaped adsorption in these flexible ZIFs. Finally, we show that the endothermic phase change of these frameworks provides intrinsic heat management during gas adsorption.

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Effects of Covalency on Anionic Redox Chemistry in Semiquinoid-Based Metal–Organic Frameworks

Ziebel

Gaggioli

Turkiewicz

et al. 2020

J. Am. Chem. Soc.

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Two iron–semiquinoid framework materials, (H2NMe2)2Fe2(Cl2 dhbq)3 (1) and (H2NMe2)4Fe3(Cl2 dhbq)3(SO4)2 (Cl2 dhbq n– = deprotonated 2,5-dichloro-3,6-dihydroxybenzoquinone) (2-SO 4 ), are shown to possess electrochemical capacities of up to 195 mAh/g. Employing a variety of spectroscopic methods, we demonstrate that these exceptional capacities arise from a combination of metal- and ligand-centered redox processes, a result supported by electronic structure calculations. Importantly, similar capacities are not observed in isostructural frameworks containing redox-inactive metal ions, highlighting the importance of energy alignment between metal and ligand orbitals to achieve high capacities at high potentials in these materials. Prototype lithium-ion devices constructed using 1 as a cathode demonstrate reasonable capacity retention over 50 cycles, with a peak specific energy of 533 Wh/kg, representing the highest value yet reported for a metal–organic framework. In contrast, the capacities of devices using 2-SO 4 as a cathode rapidly diminish over several cycles due to the low electronic conductivity of the material, illustrating the nonviability of insulating frameworks as cathode materials. Finally, 1 is further demonstrated to access similar capacities as a sodium-ion or potassium-ion cathode. Together, these results demonstrate the feasibility and versatility of metal–organic frameworks as energy storage materials for a wide range of battery chemistries.

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Confinement of atomically defined metal halide sheets in a metal–organic framework

Gonzalez

Turkiewicz

Darago

et al. 2019

Nature

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Assembling Hierarchical Cluster Solids with Atomic Precision

et al. 2014

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Hierarchical solids created from the binary assembly of cobalt chalcogenide and iron oxide molecular clusters are reported. Six different molecular clusters based on the octahedral Co6E8 (E = Se or Te) and the expanded cubane Fe8O4 units are used as superatomic building blocks to construct these crystals. The formation of the solid is driven by the transfer of charge between complementary electron-donating and electron-accepting clusters in solution that crystallize as binary ionic compounds. The hierarchical structures are investigated by single-crystal X-ray diffraction, providing atomic and superatomic resolution. We report two different superstructures: a superatomic relative of the CsCl lattice type and an unusual packing arrangement based on the double-hexagonal close-packed lattice. Within these superstructures, we demonstrate various compositions and orientations of the clusters.

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Ferromagnetic Ordering in Superatomic Solids

Lee¹,

Liu

Bejger

et al. 2014

J. Am. Chem. Soc.

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In order to realize significant benefits from the assembly of solid-state materials from molecular cluster superatomic building blocks, several criteria must be met. Reproducible syntheses must reliably produce macroscopic amounts of pure material; the cluster-assembled solids must show properties that are more than simply averages of those of the constituent subunits; and rational changes to the chemical structures of the subunits must result in predictable changes in the collective properties of the solid. In this report we show that we can meet these requirements. Using a combination of magnetometry and muon spin relaxation measurements, we demonstrate that crystallographically defined superatomic solids assembled from molecular nickel telluride clusters and fullerenes undergo a ferromagnetic phase transition at low temperatures. Moreover, we show that when we modify the constituent superatoms, the cooperative magnetic properties change in predictable ways.

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Ari Turkiewicz

Influence of Metal Substitution on the Pressure-Induced Phase Change in Flexible Zeolitic Imidazolate Frameworks

Effects of Covalency on Anionic Redox Chemistry in Semiquinoid-Based Metal–Organic Frameworks

Confinement of atomically defined metal halide sheets in a metal–organic framework

Assembling Hierarchical Cluster Solids with Atomic Precision

Ferromagnetic Ordering in Superatomic Solids

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