Ruggero Valli, Selma E. de Mink, Stephen Justham, Thomas Callister, Cole Johnston, Daniel Kresse, Norbert Langer, Amanda C. Rubio, Alejandro Vigna-Gómez, Chen Wang

Supernovae, the explosive deaths of massive stars, create heavy elements and form black holes and neutron stars. These compact objects often receive a velocity at formation, a "kick" whose physical origin remains debated. We investigate kicks in Be X-ray binaries, containing a neutron star and a rapidly spinning companion. We identify two distinct populations: one with kicks below $10\,\rm{km}\,\rm{s}^{-1}$, much lower than theoretical predictions, and another with kicks around $100\,\rm{km}\,\rm{s}^{-1}$, that shows evidence for being aligned within 5 degrees of the progenitor's rotation axis. The distribution of progenitor masses for the two populations have medians around $2.3\,\rm{M}_\odot$ and $4.9\,\rm{M}_\odot$, corresponding to stars with birth masses of about $10\,\rm{M}_\odot$ and $15\,\rm{M}_\odot$. The second component matches the low-velocity mode observed in isolated pulsars. Combined with the known high-velocity component, which dominates isolated pulsars, this suggests three distinct kick modes. These results reveal previously unrecognized diversity in neutron-star formation.