Novel cosmic-ray electron and positron constraints on MeV dark matter particles Auteur(s): Lavalle J., Boudaud Mathieu, Salati Pierre (Document sans référence bibliographique) 2016-12-22 Résumé: MeV dark matter (DM) particles annihilating or decaying to electron-positron pairs cannot, in principle, be observed via local cosmic-ray (CR) measurements because of the shielding solar magnetic field. In this Letter, we take advantage of the fact that the Voyager I spacecraft, which does measure CRs, has crossed the heliopause in 2012 and can actually, since then, detect interstellar CRs. This opens up a new avenue to probe DM in the sub-GeV energy/mass range that we first exploit here. From a complete description of the transport of electrons and positrons at low energy, we derive predictions for both the secondary astrophysical background and the pair production mechanisms relevant to DM annihilation or decay down to the MeV mass range. Interestingly, we show that reacceleration may push positrons up to energies larger than the DM particle mass. We combine the constraints from the Voyager and AMS-02 data to get novel limits covering a very extended DM particle mass range, from MeV to TeV. In the MeV mass range, our limits reach annihilation cross sections of order $\langle \sigma v\rangle \sim 10^{-28}{\rm cm^3/s}$. Though extracted from a completely different and new probe, these bounds have a strength similar to those obtained with the cosmic microwave background (CMB) --- they are even more stringent for p-wave annihilation.