Abstract
It is well known that the association of parahydrogen (pH2) with an unsaturated molecule or a transient metalorganic complex can enhance the intensity of NMR signals; the effect is known as parahydrogen-induced polarization (PHIP). During recent decades, numerous methods were proposed for converting pH2-derived nuclear spin order to the observable magnetization of protons or other nuclei of interest, usually 13C or 15N. Here, we analyze the constraints imposed by the topological symmetry of the spin systems on the amplitude of transferred polarization. We find that in asymmetric systems, heteronuclei can be polarized to 100%. However, the amplitude drops to 75% in A2BX systems and further to 50% in A3B2X systems. The latter case is of primary importance for biological applications of PHIP using sidearm hydrogenation (PHIP-SAH). If the polarization is transferred to the same type of nuclei, i.e., 1H, symmetry constraints impose significant boundaries on the spin-order distribution. For AB, A2B, A3B, A2B2, AA’(AA’) systems, the maximum average polarization for each spin is 100%, 50%, 33.3%, 25%, and 0, respectively, (where A and B (or A’) came from pH2). Remarkably, if the polarization of all spins in a molecule is summed up, the total polarization grows asymptotically with ~1.27N and can exceed 2 in the absence of symmetry constraints (where N is the number of spins). We also discuss the effect of dipole–dipole-induced pH2 spin-order distribution in heterogeneous catalysis or nematic liquid crystals. Practical examples from the literature illustrate our theoretical analysis.
Highlights
Parahydrogen-induced polarization (PHIP) is a cost-efficient and fast method to polarize nuclear spins [1]
The total wave function of the H2 nuclei is antisymmetric under the exchange of two nuclei, so the quantum numbers of the rotational states take even values [2]. oH2 is represented by three nuclear spin states, | T0 = | αβ √+2| βα, | T+ = | αα, and | T− = | ββ
This selection is dictated by the generalized Pauli principle, which states that the total wave function of two protons
Summary
Parahydrogen-induced polarization (PHIP) is a cost-efficient and fast method to polarize nuclear spins [1]. The total wave function of the H2 nuclei is antisymmetric under the exchange of two nuclei (two fermions), so the quantum numbers of the rotational states take even values [2]. OH2 is represented by three nuclear spin states, | T0 = | αβ √+2| βα , | T+ = | αα , and | T− = | ββ These three nuclear spin states are symmetric under spin exchange, necessitating odd rotational quantum numbers [2]. This selection is dictated by the generalized Pauli principle, which states that the total wave function of two protons
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