Steady-State Free Precession NMR in the Presence of Heteronuclear Couplings and Decoupling: More Than Meets the Eye

TL;DR

This paper investigates how heteronuclear couplings affect steady-state free precession (SSFP) NMR signals, revealing deviations from ideal behavior and spectral distortions that are larger than in traditional Fourier Transform NMR, especially under certain experimental conditions.

Contribution

It demonstrates the impact of heteronuclear couplings on SSFP NMR, providing analysis and experimental validation of deviations from isolated spin-half models and discussing ways to control these effects.

Findings

Heteronuclear couplings cause significant deviations in SSFP responses.

Spectral distortions in SSFP can be larger than in FT NMR.

Interpulse delays resonating with couplings amplify distortions.

Abstract

Fourier Transform (FT) has been a mainstay of analytical 13C and 15N NMR. On the other hand it has been shown that Steady State Free Precession (SSFP) experiments which depart from this scheme can, under certain conditions, endow 13C and 15N small molecule NMR with comparable sensitivity and resolution. SSFP is one of the earliest and most widely used NMR pulse sequences, yet its analyses have focused on isolated spin-half ensembles such as water. The present study demonstrates that significant deviations from such isolated spin-half behavior may occur when SSFP is applied in the presence of spin-spin couplings. Even in the simplest case supporting such couplings, a single 13C J coupled to a 1H, departures from the isolated spin-half behavior arise in the 13C SSFP response, both in the absence and in the presence of 1H spin decoupling. In the former case deviations are produced by the differential relaxation of antiphase two-spin terms generated by the pulse train; in the latter case, magnified interferences may arise between the SSFP pulses and the coherent perturbation arising upon 1H decoupling. Although both phenomena are also known in FT NMR, the spectral distortions that they will originate may be much larger in the SSFP case, particularly if interpulse delays in large flip angle SSFP pulse trains resonate with the coupling perturbations. The origins of these effects are here analyzed for heteronuclear spin-half systems and corroborated with 13C NMR SSFP experiments recorded under different conditions. Additional considerations aimed at magnifying or suppressing these effects, as well as extensions to more complex scenarios, are also briefly discussed.