London Dispersion Governs the Interaction Mechanism of Small Polar and Nonpolar Molecules in Metal–Organic Frameworks

Melix, Patrick; Heine, Thomas

doi:10.1021/acs.jpcc.0c02966

Cited by 9 publications

(12 citation statements)

References 39 publications

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“…In order to reduce the stress during solvent removal, DMF was exchanged with dichloromethane (DCM) before desolvation under reduced pressure at 423 K during 16 h (procedure b). DCM is a molecule with a smaller kinetic diameter (4.70 Å) 63 , smaller dipole moment (1.62 D) 64 and low boiling point (312.6 K), therefore, in comparison to DMF, it should be easier to remove. According to PXRD (Figure 4), the desolvation of the macro-sized 1b and micron-sized crystals 2b triggers the structural transformation from op to cp phase, in which the framework undergoes a significant shearing to minimize the amount of void space.…”

Section: Desolvationmentioning

confidence: 99%

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Tailoring adsorption induced switchability of a pillared layer MOF by crystal size engineering

et al. 2021

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Section: Desolvationmentioning

confidence: 99%

“…However, as the size differs considerably, significant differences in maximal loadings per formula unit of MOF (nmax) can be estimated (Table 1). 63 Hence, the total adsorption energy (nmaxEads) per Zn2(2,6ndc)2dabco formula unit (fu) of MOF decreases continuously from chloromethane to tetrachloromethane (Tab. 1).…”

Section: Samples Desolvated From Dcm (B)mentioning

confidence: 99%

Tailoring adsorption induced switchability of a pillared layer MOF by crystal size engineering

et al. 2021

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“…Under the dynamically applied bias, the inherent dipole moments align themselves in the direction of the external stimuli applied electric fields. [ 66 ] Figure 6d shows the energy band diagram of Cu‐MOCs based on Al/Cu‐MOCs/Si MIS‐CAP structures. The actual band positions of MOCs differ with the metal centers and organic ligands systems.…”

Section: Resultsmentioning

confidence: 99%

Integration of High‐Performance Cost‐Effective Copper‐Metal‐Organic‐Nanocluster‐based Gate Dielectric for Next‐Generation CMOS Applications

Gupta

Kumar

Sharma

2021

Adv Elect Materials

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The suitability of metal‐organic frameworks (MOFs) as functional materials for future electronic logic devices with desirable dielectric constant, bandgap, high‐quality interface, low leakage current, and better compatibility is still an open challenge. Owing to the synergistic complementary properties of MOFs systems, a low‐cost copper‐metal‐organic nanoclusters (Cu‐MOCs) has been synthesized comprising inorganic copper metal unit allied organic m‐toluic acid ligand by facile sol–gel strategy. It offers large‐area thin‐films uniformity, high dielectric constant (κ ≈ 5.49), improved interfacial properties, dynamic switching behavior with the stimuli field, and extends the realization of metal‐organic‐framework dielectric for scalable complementary‐metal‐oxide‐semiconductor (CMOS) logic applications over customary hybrid counterparts. Various techniques such as single crystal X‐ray diffraction, X‐ray photoelectron spectroscopy, thermogravimetric analysis, and energy dispersive X‐ray spectroscopy have been used to validate the Cu‐MOCs formulation. In particular, the fabricated Cu‐MOCs, metal–insulator–semiconductor structures exhibit promising dynamic switching behavior responsive to the applied field, hysteresis‐free capacitance–voltage characteristics, low interfacial trap density (≈1.4 × 1011 eV−1 cm−2), low effective oxide charges (≈1.1 × 1011 cm−2), and noteworthy small leakage current density (≈1.29 nA cm−2 @ 1 V) ever since in electrical analysis. Cost‐effective novel Cu‐MOCs successfully demonstrate high‐performance, reliable gate dielectrics for next‐generation CMOS logic devices.

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“…We employ our previously published Ligand-Field Molecular Mechanics (LFMM) simulation setup for DUT-8(Ni). [34,35] We perform three types of MD simulations: 1) CO2 in the rigid A conformer of DUT-8(Ni) using a fully flexible cell (NσT ensemble); 2) CO2 in the B conformer with a fully flexible cell (NσT ensemble); 3) CO2 in the B conformer with a fixed cell (NVT ensemble) in the op state. For details of the LFMM parametrization see ref [34] , details of the MD simulations are given in the Supporting Information and adhere to the previous publications.…”

Section: Simulationsmentioning

confidence: 99%

Investigation of CO2 Orientational Dynamics through Simulated NMR Line Shapes

Melix

Heine

2021

Preprint

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The dynamics of CO2 in third generation Metal-Organic Frameworks can be experimentally observed by 13C NMR spectroscopy. The obtained line shapes directly correlate with the motion of the adsorbed CO2, which in turn are readily available from classical molecular dynamics simulations. In this article, we present our publicly available implementation of an algorithm to calculate NMR line shapes from MD trajectories in a matter of minutes on any current personal computer. We apply the methodology to study an effect observed experimentally when adsorbing CO2 in different samples of the pillared layer MOF DUT-8(Ni). In 13C NMR experiments of adsorbed CO2 in this MOF, small (rigid) crystals result in narrower NMR line shapes than larger (flexible) crystals. The reasons for the higher mobility of CO2 inside the smaller crystals is unknown. Our ligand field molecular mechanics simulations provide atomistic insight into the effects visible in NMR experiments with limited computational effort.

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London Dispersion Governs the Interaction Mechanism of Small Polar and Nonpolar Molecules in Metal–Organic Frameworks

Cited by 9 publications

References 39 publications

Tailoring adsorption induced switchability of a pillared layer MOF by crystal size engineering

Tailoring adsorption induced switchability of a pillared layer MOF by crystal size engineering

Integration of High‐Performance Cost‐Effective Copper‐Metal‐Organic‐Nanocluster‐based Gate Dielectric for Next‐Generation CMOS Applications

Investigation of CO2 Orientational Dynamics through Simulated NMR Line Shapes

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