Abstract
The resolution of proton solid-state NMR spectra is usually limited by broadening arising from dipolar interactions between spins. Magic-angle spinning alleviates this broadening by inducing coherent averaging. However, even the highest spinning rates experimentally accessible today are not able to completely remove dipolar interactions. Here, we introduce a deep learning approach to determine pure isotropic proton spectra from a two-dimensional set of magic-angle spinning spectra acquired at different spinning rates. Applying the model to 8 organic solids yields high-resolution 1H solid-state NMR spectra with isotropic linewidths in the 50–400 Hz range.
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CITATION STYLE
Cordova, M., Moutzouri, P., Simões de Almeida, B., Torodii, D., & Emsley, L. (2023). Pure Isotropic Proton NMR Spectra in Solids using Deep Learning. Angewandte Chemie - International Edition, 62(8). https://doi.org/10.1002/anie.202216607
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