Kaniadakis holographic dark energy: observational constraints and global dynamics

We investigate Kaniadakis-holographic dark energy by confronting it with observations. We perform a Markov Chain Monte Carlo analysis using cosmic chronometers, supernovae type Ia, and Baryon Acoustic Oscillations data. Concerning the Kaniadakis parameter, we find that it is constrained around zero, namely around the value in which Kaniadakis entropy recovers standard Bekenstein-Hawking one. Additionally, for the present matter density parameter $\Omega_m^{(0)}$, we obtain a value slightly smaller compared to $\Lambda$CDM scenario. However, for the present dimensionless Hubble constant, the combined dataset analysis gives $h=0.722^{+0.010}_{-0.010}$, which is consistent within $1\sigma$ with its direct measurements through Cepheids, thus Kaniadakis-holographic dark energy offers an alleviation to the $H_0$ tension. Furthermore, we reconstruct the evolution of the Hubble, deceleration and jerk parameters extracting the deceleration-acceleration transition redshift as $z_T = 0.65^{+0.13}_{-0.11}$. Finally, performing a detailed local and global dynamical system analysis, we find that the past attractor of the Universe is the matter-dominated solution, while the late-time stable solution is the dark-energy-dominated one.