Homonuclear dipolar recoupling under ultra-fast magic-angle spinning: Probing 19F−19F proximities by solid-state NMR

We describe dipolar recoupling methods that accomplish, at high magic-angle spinning (MAS) frequencies, the excitation of double-quantum (DQ) coherences between spin-1/2 nuclei. We employ rotor-synchronized symmetry-based pulse sequences which are either γ-encoded or non-γ-encoded. The sensitivity and the robustness to both chemical-shift anisotropy and offset are examined. We also compare different techniques to avoid signal folding in the indirect dimension of two-dimensional double-quantum ↔ single-quantum (DQ−SQ) spectra. This comprehensive analysis results in the identification of satisfactory conditions for dipolar 19F−19F recoupling at high magnetic fields and high MAS frequencies. The utility of these recoupling methods is demonstrated with high-resolution DQ−SQ NMR spectra, which allow probing 19F−19F proximities in powered fluoroaluminates.