Magnetic field induced delocalization in hybrid electron-nuclear spin ensembles

We use field-cycling-assisted dynamic nuclear polarization to demonstrate magnetic-field-dependent activation of nuclear spin transport from otherwise isolated strongly-hyperfine-coupled sites. With the help of a toy model comprising electron and nuclear spins, we recast our observations in terms of a dynamic phase diagram featuring zones of active or forbidden nuclear spin current separated by boundaries defined by the interplay between spin Zeeman, dipolar, and hyperfine couplings. Analysis of the polarization transport as a function of the driving field reveals the presence of many-body excitations stemming from the hybrid electron-nuclear nature of the system. These findings could prove relevant in applications to spin-based quantum information processing and nanoscale sensing.