2 research outputs found
Zero-Field J-spectroscopy of Quadrupolar Nuclei
Zero- to ultralow-field (ZULF) nuclear magnetic resonance (NMR) is a version
of NMR that allows studying molecules and their transformations in the regime
dominated by intrinsic spin-spin interactions. While spin dynamics at zero
magnetic field can be probed indirectly, J-spectra can also be measured at zero
field by using non-inductive sensors, for example, optically-pumped
magnetometers (OPMs). A J-spectrum can be detected when a molecule contains at
least two different types of magnetic nuclei (i.e., nuclei with different
gyromagnetic ratios) that are coupled via J-coupling. Up to date, no pure
J-spectra of molecules featuring the coupling to quadrupolar nuclei were
reported. Here we show that zero-field J-spectra can be collected from
molecules containing quadrupolar nuclei with I = 1 and demonstrate this for
solutions containing various isotopologues of ammonium cations. Lower ZULF NMR
signals are observed for molecules containing larger numbers of deuterons
compared to protons; this is attributed to less overall magnetization and not
to the scalar relaxation of the second kind. We analyze the energy structure
and allowed transitions for the studied molecular cations in detail using
perturbation theory and demonstrate that in the studied systems, different
lines in J-spectra have different dependencies on the magnetic pulse length
allowing for unique on-demand zero-field spectral editing. Precise values for
the 15N-1H, 14N-1H, and D-1H coupling constants are extracted from the spectra
and the difference in the reduced coupling constants is explained by the
secondary isotope effect. Simple symmetric cations such as ammonium do not
require expensive isotopic labeling for the observation of J-spectra and, thus,
may expand applicability of ZULF NMR spectroscopy in biomedicine and energy
storage.Comment: 39 pages, 5 figure
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Zero-Field J-spectroscopy of Quadrupolar Nuclei
Zero- to ultralow-field (ZULF) nuclear magnetic resonance (NMR) is a version
of NMR that allows studying molecules and their transformations in the regime
dominated by intrinsic spin-spin interactions. While spin dynamics at zero
magnetic field can be probed indirectly, J-spectra can also be measured at zero
field by using non-inductive sensors, for example, optically-pumped
magnetometers (OPMs). A J-spectrum can be detected when a molecule contains at
least two different types of magnetic nuclei (i.e., nuclei with different
gyromagnetic ratios) that are coupled via J-coupling. Up to date, no pure
J-spectra of molecules featuring the coupling to quadrupolar nuclei were
reported. Here we show that zero-field J-spectra can be collected from
molecules containing quadrupolar nuclei with I = 1 and demonstrate this for
solutions containing various isotopologues of ammonium cations. Lower ZULF NMR
signals are observed for molecules containing larger numbers of deuterons
compared to protons; this is attributed to less overall magnetization and not
to the scalar relaxation of the second kind. We analyze the energy structure
and allowed transitions for the studied molecular cations in detail using
perturbation theory and demonstrate that in the studied systems, different
lines in J-spectra have different dependencies on the magnetic pulse length
allowing for unique on-demand zero-field spectral editing. Precise values for
the 15N-1H, 14N-1H, and D-1H coupling constants are extracted from the spectra
and the difference in the reduced coupling constants is explained by the
secondary isotope effect. Simple symmetric cations such as ammonium do not
require expensive isotopic labeling for the observation of J-spectra and, thus,
may expand applicability of ZULF NMR spectroscopy in biomedicine and energy
storage