Efficient conversion of anti-phase spin order of protons into 15N magnetization using SLIC-SABRE

TL;DR

This paper demonstrates that the anti-phase spin order of protons in SABRE experiments at high magnetic fields can be efficiently converted into 15N magnetization by modifying existing transfer methods, supported by theory and experiments.

Contribution

It reveals that the proton spin order in SABRE is anti-phase rather than singlet and proposes modifications to transfer methods for improved polarization transfer.

Findings

Anti-phase proton spin order is dominant in high-field SABRE.

Modified transfer methods improve 15N polarization efficiency.

Theoretical analysis supports experimental results.

Abstract

SABRE (Signal Amplification By Reversible Exchange) is a technique for enhancement of NMR (Nuclear Magnetic Resonance) signals, which utilizes parahydrogen (pH2, the H2 molecule in its nuclear spin state) as a source of non-thermal spin order. In SABRE experiments, pH2 binds to an organometallic complex with a to-be-polarized substrate; subsequently, spin order transfer takes place and the substrate acquires non-thermal spin polarization resulting in strong NMR signal enhancement. In this work we argue that the spin order of H2 in SABRE experiments performed at high magnetic fields is not necessarily the singlet order but rather anti-phase polarization, $S_{1z}S_{2z}$. Although SABRE exploits pH2, i.e., the starting spin order of H2 is supposed to be the singlet order, in solution S-T0 conversion becomes efficient once pH2 binds to a complex. Such a variation of the spin order, which becomes $S_{1z}S_{2z}$, has an important consequence: NMR methods used for transferring SABRE polarization need to be modified. Here we demonstrate that methods proposed for the initial singlet order may not work for the S_1z S_2z order; however, a simple modification makes them efficient again. A theoretical treatment of the problem under consideration is proposed; these considerations are supported by high-field SABRE experiments. Hence, for efficient use of SABRE one should note that polarization formation is a complex multi-stage process: careful optimization of this process may not only deal with chemical aspects but also with the spin dynamics, including the spin dynamics of H2.