R. Adam Kinney scite author profile

We report a strategy for realizing tunable electrical conductivity in metal-organic frameworks (MOFs) in which the nanopores are infiltrated with redox-active, conjugated guest molecules. This approach is demonstrated using thin-film devices of the MOF Cu3(BTC)2 (also known as HKUST-1; BTC, benzene-1,3,5-tricarboxylic acid) infiltrated with the molecule 7,7,8,8-tetracyanoquinododimethane (TCNQ). Tunable, air-stable electrical conductivity over six orders of magnitude is achieved, with values as high as 7 siemens per meter. Spectroscopic data and first-principles modeling suggest that the conductivity arises from TCNQ guest molecules bridging the binuclear copper paddlewheels in the framework, leading to strong electronic coupling between the dimeric Cu subunits. These ohmically conducting porous MOFs could have applications in conformal electronic devices, reconfigurable electronics, and sensors.

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A Nonclassical Dihydrogen Adduct of S = ¹/₂ Fe(I)

Lee

Kinney

Hoffman

et al. 2011

J. Am. Chem. Soc.

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We have exploited the capacity of the ‘(SiPiPr3)Fe(I)’ scaffold to accommodate additional axial ligands and have characterized the mononuclear, S = ½ H2-adduct complex (SiPiPr3)FeI(H2). EPR and ENDOR data, in the context of X-ray structural results, reveal that this complex provides a highly unusual example of an open-shell metal complex that binds dihydrogen as a ligand. The H2 ligand at 2 K dynamically reorients within the ligand-binding pocket, tunneling among the energy minima created by strong interactions with the three Fe-P bonds.

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Modeling the Signatures of Hydrides in Metalloenzymes: ENDOR Analysis of a Di-iron Fe(μ-NH)(μ-H)Fe Core

et al. 2012

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The application of 35 GHz pulsed EPR and ENDOR spectroscopies has established that the biomimetic model complex L3Fe(μ-NH)(μ-H)FeL3 (L3 = [PhB(CH2PPh2)3]-) complex, 3, is a novel S = ½ type-III mixed-valence di-iron II/III species, in which the unpaired electron is shared equally between the two iron centers. 1,2H and 14,15N ENDOR measurements of the bridging imide are consistent with an allyl radical molecular orbital model for the two bridging ligands. Both the (μ-H) and the proton of the (μ-NH) of the crystallographically characterized 3 show the proposed signature of a ‘bridging’ hydride that is essentially equidistant between two ‘anchor metal ions: a rhombic dipolar interaction tensor, T ≈ [T, -T, 0]. The point-dipole model for describing the anisotropic interaction of a bridging H as the sum of the point-dipole couplings to the ‘anchor’ metal ions reproduces this signature with high accuracy, as well as the axial tensor of a terminal hydride, T ≈ [-T, -T, 2T], thus validating both the model and the signatures. This validation in turn lends strong support to the assignment, based on such a point-dipole analysis, that the molybdenum-iron cofactor of nitrogenase contains two [Fe-H--Fe] bridging-hydride fragments in the catalytic intermediate that has accumulated four reducing equivalents (E4). Analysis further reveals a complementary similarity between the isotropic hyperfine couplings for the bridging hydrides in 3 and E4. This study provides a foundation for spectroscopic study of hydrides in a variety of reducing metalloenzymes in addition to nitrogenase.

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R. Adam Kinney

Tunable Electrical Conductivity in Metal-Organic Framework Thin-Film Devices

A Nonclassical Dihydrogen Adduct of S = ¹/₂ Fe(I)

Modeling the Signatures of Hydrides in Metalloenzymes: ENDOR Analysis of a Di-iron Fe(μ-NH)(μ-H)Fe Core

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R. Adam Kinney

Tunable Electrical Conductivity in Metal-Organic Framework Thin-Film Devices

A Nonclassical Dihydrogen Adduct of S = 1/2 Fe(I)

Modeling the Signatures of Hydrides in Metalloenzymes: ENDOR Analysis of a Di-iron Fe(μ-NH)(μ-H)Fe Core

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A Nonclassical Dihydrogen Adduct of S = ¹/₂ Fe(I)