Abstract
Strong coupling of nuclear spins, which is achieved when their scalar coupling is greater than or comparable to the difference in their Larmor precession frequencies in an external magnetic field, gives rise to efficient coherent longitudinal polarization transfer. The strong coupling regime can be achieved when the external magnetic field is sufficiently low, as is reduced proportional to the field strength. In the present work, however, we demonstrate that in heteronuclear spin systems these simple arguments may not hold, since heteronuclear spin-spin interactions alter the value. The experimental method that we use is two-field nuclear magnetic resonance (NMR), exploiting sample shuttling between the high field, at which NMR spectra are acquired, and the low field, where strong couplings are expected and at which NMR pulses can be applied to affect the spin dynamics. By using this technique, we generate zero-quantum spin coherences by means of a nonadiabatic passage through a level anticrossing and study their evolution at the low field. Such zero-quantum coherences mediate the polarization transfer under strong coupling conditions. Experiments performed with a -labeled amino acid clearly show that the coherent polarization transfer at the low field is pronounced in the spin subsystem under proton decoupling. However, in the absence of proton decoupling, polarization transfer by coherent processes is dramatically reduced, demonstrating that heteronuclear spin-spin interactions suppress the strong coupling regime, even when the external field is low. A theoretical model is presented, which can model the reported experimental results.
Highlights
The topological and conformational information provided by scalar couplings lies at the foundation of the analytical power of nuclear magnetic resonance (NMR) spectroscopy (Ernst et al, 1987; Keeler, 2005; Levitt, 2008; Cavanagh, 2007)
Our results identify how heteronuclear couplings alter homonuclear couplings at low magnetic fields, which could be exploited in low-field NMR methodology and may be considered in further developments of total correlation spectroscopy (TOCSY; Braunschweiler and Ernst, 1983) mixing sequences in highfield NMR
We present a study of coherent polarization transfer in a system of coupled 13C nuclei
Summary
The topological and conformational information provided by scalar couplings lies at the foundation of the analytical power of nuclear magnetic resonance (NMR) spectroscopy (Ernst et al, 1987; Keeler, 2005; Levitt, 2008; Cavanagh, 2007). For homonuclear couplings, the transition between the weak and strong coupling regimes occurs in a range of magnetic fields where the Zeeman interaction is still dominant (Ivanov et al, 2006, 2008, 2014; Appelt et al, 2010; Türschmann et al, 2014) This transition between weak and strong couplings can be investigated by varying the magnetic field applied to the sample on a high-field magnet, which is usually performed by moving the sample through the stray field with a shuttle system (Roberts and Redfield, 2004a, b; Redfield, 2012; Wagner et al, 1999; Bryant and Korb, 2005; Goddard et al, 2007; Chou et al, 2016, 2017; Charlier et al, 2013; Cousin et al, 2016a, b; Zhukov et al, 2018; Kiryutin et al, 2016). Our results identify how heteronuclear couplings alter homonuclear couplings at low magnetic fields, which could be exploited in low-field NMR methodology and may be considered in further developments of total correlation spectroscopy (TOCSY; Braunschweiler and Ernst, 1983) mixing sequences in highfield NMR
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