Cyclic and Slice-Selective J Cross Polarization for Heteronuclear Editing and Localized NMR

We thank K.-H. Spohn for discussions and B. Striebel, J. Ankele, and J. Wiringer for assistance in the course of the experiments. This work was supported by the Deutsche Forschungsgemeinschaft.

A new principle for spatially localized solid-state NMR is reported. Polarization transfer (or cross-polarization or more generally spin-order transfer) is strongly susceptible to deviations from the resonance conditions. Hartmann-Hahn matching and matching to the local field in dipolar order states

Selective 1 H-13 C inverse NMR experiments based on heteronuclear cross-polarization (HCP) are presented. Practical details on the implementation of one-bond [ 1 J C,H ] optimized and pseudo-3D HCP experiments combined with gradient coherence selection are reported. On the other hand, accurate value

## Abstract New spin‐state‐selective (S^3^) NMR pulse sequences exclusively applying cross‐polarization schemes to achieve optimum homonuclear and heteronuclear ^1^HX coherence transfer are reported for the simple and accurate measurement of the magnitude and sign of heteronuclear coupling constan

This work predominantly refers to in vivo spectroscopy. The objective is to record volume-selectively \({ }^{13} \mathrm{C}\) signals by the aid of a new, simple, and robust localization technique. \(J\) cross polarization (or coherent rotating-frame polarization transfer) between coupled \({ }^{1}

## Abstract Insect exoskeleton, multiply labeled with ^13^C and ^15^N, was examined by rotational‐echo double‐resonance (REDOR) and double‐cross‐polarization (DCP) magic‐angle spinning ^13^C NMR. Low levels of incorporation of label make the analysis of these samples a practical test of the relativ