Recovery time reduction to decrease experimental duration (R2D2): A simple and universal method to accelerate NMR experiments.

Acceleration techniques for one dimensional Nuclear Magnetic Resonance (1D NMR) are very useful, both for NMR enthusiasts and for chemists that use NMR for structural elucidation. To the latter, such techniques need to be straightforward. Recovery time Reduction to Decrease the experimental Duration (R2D2) relies on the incremental reduction of a pulse sequence's Recycle Time (TR). A pseudo-2D spectrum is acquired and after two Fourier transform, extraction and addition of the central rows, a 1D spectrum is obtained. Not only can it be applied to any pulse sequence that contains a TR, but it also requires only a list of recovery times and 2D processes to operate. With this method, we were able to easily reduce the experimental time by a factor of 2 and up to 4 using single-pulse, APT and DEPT 13C sequences. Moreover, R2D2 has the potential to be used on other low abundance nuclei (such as 15N or 2H) and numerous other pulse sequences.

MISSTEC-S: A fast 1H pulse calibration from spectra simultaneously produced by a spin echo and a stimulated echo.

Radio-Frequency (RF) pulse calibration is an essential step in guaranteeing both optimum acquisition quality in multi-pulse NMR and accurate results in quantitative experiments. Most existing methods are based on a series of spectra for which the flip angle of one or more pulses is progressively incremented, implying a significant experiment time. In order to circumvent this drawback, we have previously proposed an approach based on the acquisition of a spin echo and a stimulated echo - the MISSTEC sequence - which requires only 8 s to determine the PW90-1H, while it is several minutes in the case of the use of a nutation curve. In this work, a new sequence for RF calibration is presented: MISSTEC-S. It is derived from the previously proposed MISSTEC sequence, but the observation of echoes in presence of magnetic field gradient is replaced by the observation of FIDs. This modification allows both spectra to be phased, while imposing a strong constraint on the Mixing Time (TM). However, the relationship used to calculate the flip angle is only correct when TM is small enough to neglect longitudinal relaxation during this delay. In order to reduce TM, the first FID is truncated during acquisition and subsequently lengthened using points from the second FID. Results obtained with MISSTEC-S were compared to those obtained from a complete nutation curve and an excellent correlation was observed, although the experimental time to obtain the PW90 is dramatically reduced.