Dynamical polarization of the fermion parity in a nanowire Josephson junction

Josephson junctions in InAs nanowires proximitized with an Al shell can host gate-tunable Andreev bound states. Depending on the bound state occupation, the fermion parity of the junction is even or odd. Coherent control of Andreev bound states has recently been achieved within each parity sector, but it is impeded by incoherent parity switches due to excess quasiparticles in the superconducting environment. Here, we embed the junction in a superconducting LC resonator and show that we can polarize the fermion parity dynamically using microwave pulses. We demonstrate polarization up to 94% +- 1% (89% +- 1%) for the even (odd) parity as verified by single shot parity-readout. Finally, we apply this scheme to probe the flux-dependent transition spectrum of the even or odd parity sector selectively, without any post-processing or heralding. These results enable fast initialization of ABS parity and introduce an additional experimental control knob for studying parity switching processes, highly relevant for Andreev and topological qubits.