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Abstract

Nuclear magnetism underpins areas such as medicine in magnetic resonance imaging (MRI). Hyperpolarization of nuclei enhances the quantity and quality of information that can be determined from these techniques by increasing their signal to noise ratios by orders of magnitude. However, some of these hyperpolarization techniques rely on the use of low to ultralow magnetic fields (ULF) (nTs-mTs), where empirical data on how nuclear magnetism behaves is lacking. The broadband character and ultrasensitive field sensitivity of superconducting quantum interference devices (SQUID) allow for probing nuclear magnetism at these fields, where other magnetometers, such as Faraday coils and flux gates do not. To this end, we designed a hyperpolarization reactor to hyperpolarize [1-13C]pyruvate with the technique, signal amplification by reversible exchange in shield enables alignment transfer to heteronuclei (SABRE-SHEATH). Afterwards, we were able to characterize the field sensitivity of our setup by simulating the filled reactor in relation to its placement in our ultralow noise, ULF MRI setup. Using the results of the simulations, we determined that our hyperpolarization setup results in a 13C polarization of 0.4%, a signal enhancement of ~100 000 000 versus the predicted thermal equilibrium signal at earth field (~50 μT). This results in a 13C signal of 7.44±0.91 pT, which with our ultralow noise setup, opens the possibility for the first direct detection of nuclear magnetism without system perturbation.