High-energy neutrino emission from tidal disruption event outflow-cloud interactions
Abstract
Tidal disruption events (TDEs), characterized by their luminous transients and high-velocity outflows, have emerged as plausible sources of high-energy neutrinos contributing to the diffuse neutrino. In this study, we calculate the contribution of TDEs to the diffuse neutrino by employing the outflow-cloud model within the TDE framework. Our analysis indicates that the contribution of TDEs becomes negligible when the redshift Z exceeds 2. Employing a set of fiducial values, which includes outflow energy E kin=1051 erg, a proton spectrum cutoff energy E p,max=100 PeV, a volume TDE rate N=8 × 10-7\ Mpc-3\ year-1, covering fraction of clouds CV=0.1, energy conversion efficiency in the shock η =0.1, and a proton spectrum index =-1.7, we find that TDEs can account for approximately 80\% of the contribution at energies around 0.3 PeV. Additionally, TDEs still contribute around 18\% to the IceCube data below 0.1 PeV and the total contribution is 24+2-15\%. In addition, we also discuss the potential influence of various parameter values on the results in detail. With the IceCube data, we impose constraints on the combination of the physical parameters, i.e., Cf=NE kinC vη. Future observations or theoretical considerations would fix some physical parameters, which will help to constrain some individual parameters of TDEs.
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