Abstract
An efficient protocol for the calculation of 13C pNMR shifts in metal–organic frameworks based on Cu(ii) paddlewheel dimers is proposed, which involves simplified structural models, optimised using GFN2-xTB for the high-spin state, and CAM-B3LYP-computed NMR and EPR parameters. Models for hydrated and activated HKUST-1 and hydrated STAM MOFs with one, two and three Cu dimers have been used. The electronic ground states are low-spin and diamagnetic, with pNMR shifts arising from thermal population of intermediate- and high-spin excited states. Treating individual spin configurations in a broken symmetry (BS) approach, and selecting two or more of these to describe individual excited states, the magnetic shieldings of these paramagnetic states are evaluated using the approach by Hrobárik and Kaupp. The total shielding is then evaluated from a Boltzmann distribution between the energy levels of the chosen configurations. The computed pNMR shifts are very sensitive to temperature and, therefore, to the relative energies of the BS spin states. In order to reproduce the temperature dependence of the pNMR shifts seen in experiment, some scaling of the calculated energy gaps is required. A single scaling factor was applied to all levels in any one system, by fitting to experimental results at several temperatures simultaneously. The resulting scaling factor decreases with an increasing number of dimer units in the model (e.g., from ∼1.7 for mono-dimer models to 1.2 for tri-dimer models). The approach of this scaling factor towards unity indicates that models with three dimers are approaching a size where they can be considered as reasonable models for the 13C shifts of infinite MOFs. The observed unusual temperature dependencies in the latter are indicated to arise both from the “normal” temperature dependence of the pNMR shifts of the paramagnetic states and the populations of these states in the thermal equilibrium.
Highlights
Solid-state Nuclear Magnetic Resonance (NMR) spectroscopy provides a very sensitive probe of the local, atomic-scale environment of the nuclear spins present in a sample without any requirement for long-range order.[1,2,3] The sensitivity of the NMR parameters to small changes in geometry has resulted in this method being used to probe weak bonding interactions, host– guest interactions and both static and dynamic disorder
It should be noted that this is not possible for molecular benzoates, which above 1000 ppm were seen in previous work for a urea-loaded copper benzoate dimer, and in this case the computational and experimental shi s were in much better agreement.[20]
For Metal–organic frameworks (MOFs), the dimer units are much closer and can interact via the aromatic organic linkers that joint them, suggesting more sophisticated models and a proper theoretical description of the magnetic coupling between dimers will be needed. This is supported by comparing the difference in the experimental 13C shi s for the aromatic CH species in hydrated HKUST-1 and hydrated STAM-1; signals are seen at diso z 227 ppm for the CH groups between two dimers in both MOFs, but the C4 signal in STAM-1 has diso 1⁄4 178 ppm
Summary
Solid-state Nuclear Magnetic Resonance (NMR) spectroscopy provides a very sensitive probe of the local, atomic-scale environment of the nuclear spins present in a sample without any requirement for long-range order.[1,2,3] The sensitivity of the NMR parameters to small changes in geometry has resulted in this method being used to probe weak bonding interactions, host– guest interactions and both static and dynamic disorder. The versatile chemistry of MOFs, with many possible combinations of nodes and linkers, leads to a range of applications in elds as diverse as gas storage, catalysis and drug delivery.[6,7,8] Solid-state NMR spectroscopy is frequently used to study MOFs, enabling the binding of guest molecules, the dynamics of guest species within the pores, and any structural changes that can result from these to be explored.[9,10,11,12] MOFs that contain paramagnetic metal centres pose a particular challenge for NMR spectroscopy, but such materials o en have interesting and useful physical and chemical properties that can be exploited.
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