Getting the most on supernova axions

Axionlike particles (ALPs) coupled to nucleons might be copiously emitted from a supernova (SN) core. We extend existing bounds on free-streaming ALPs to the case in which these are so strongly interacting with the nuclear matter to be trapped in the SN core. For strongly interacting ALPs, we also extend the bound from the absence of an ALP-induced signal in Kamiokande-II neutrino detector at the time of SN 1987A. We find that combining the different arguments, SNe exclude values of ALP-nucleon coupling g(aN) greater than or similar to 10(-9) for ALP masses m(a) less than or similar to 1 MeV. Remarkably, in the case of canonical QCD axion models, the SN bounds exclude all values of m(a) greater than or similar to 10(-2 )eV. This result prevents the possibility for current and future cosmological surveys to detect any signatures due to hot dark matter QCD axion mass.