Model-independent Astrophysical Constraints on Leptophilic Dark Matter in the Framework of Tsallis Statistics

TL;DR

This paper establishes astrophysical constraints on leptophilic dark matter using supernova data within a Tsallis statistical framework, providing bounds on interaction scales and relic density considerations.

Contribution

It introduces a model-independent approach incorporating Tsallis statistics to derive supernova-based bounds on leptophilic dark matter interactions.

Findings

Lower bound on cutoff scale   3-12 TeV depending on q

Cooling bounds restrict   1 TeV for free-streaming

Bounds weaken for heavy dark matter due to Boltzmann suppression

Abstract

We derive model-independent astrophysical constraints on leptophilic dark matter (DM), considering its thermal production in a supernova core and taking into account core temperature fluctuations within the framework of $q$-deformed Tsallis statistics. In an effective field theory approach, where the DM fermions interact with the Standard Model via dimension-six operators of either scalar-pseudoscalar, vector-axial vector, or tensor-axial tensor type, we obtain bounds on the effective cut-off scale $\Lambda$ from supernova cooling and free-streaming of DM from supernova core, and from thermal relic density considerations, depending on the DM mass and the $q$-deformation parameter. Using Raffelt's criterion on the energy loss rate from SN1987A, we obtain a lower bound on $\Lda \gtrsim 3$ (12) TeV corresponding to $q = 1.0~(1.1)$ and an average supernova core temperature of $T_{\rm SN}=30$ MeV. From the optical depth criterion on the free-streaming of DM fermions from the outer 10\% of the SN1987A core, the cooling bound is restricted to $\Lda \gtrsim 1$ TeV. Both cooling and free-streaming bounds are insensitive to the DM mass $m_\chi$ for $m_\chi\lesssim T_{\rm SN}$, whereas for $m_\chi\gg T_{\rm SN}$, the bounds weaken significantly due to the Boltzmann-suppression of the DM number density. We also calculate the thermal relic density of the DM particles in this setup and find that it imposes an upper bound on $\Lambda^4/m_\chi^2$, which together with the cooling/free-streaming bound significantly constrains light leptophilic DM.