Overhauser enhanced liquid state nuclear magnetic resonance spectroscopy in one and two dimensions.

Nuclear magnetic resonance (NMR) is fundamental in the natural sciences, from chemical analysis and structural biology, to medicine and physics. Despite its enormous achievements, one of its most severe limitations is the low sensitivity, which arises from the small population difference of nuclear spin states. Methods such as dissolution dynamic nuclear polarization and parahydrogen induced hyperpolarization can enhance the NMR signal by several orders of magnitude, however, their intrinsic limitations render multidimensional hyperpolarized liquid-state NMR a challenge.

Large P-NMR enhancements in liquid state dynamic nuclear polarization through radical/target molecule non-covalent interaction.

Dynamic nuclear polarization (DNP) is a method to enhance the low sensitivity of nuclear magnetic resonance (NMR) spin polarization transfer from electron spins to nuclear spins. In the liquid state, this process is mediated by fast modulations of the electron-nuclear hyperfine coupling and its efficiency depends strongly on the applied magnetic field. A peculiar case study is triphenylphosphine (PPh) dissolved in benzene and doped with BDPA radical because it gives P-NMR signal enhancements of two orders of magnitude up to a magnetic field of 14.

Spin density localization and accessibility of organic radicals affect liquid-state DNP efficiency.

We report a large variation in liquid DNP performance of up to a factor of about five in coupling factor among organic radicals commonly used as polarizing agents. A comparative study of H and C DNP in model systems shows the impact of the spin density distribution and accessibility of the radical site by the target molecule.