Barrow and Tsallis entropies after the DESI DR2 BAO data

Modified cosmology based on Barrow entropy arises from the gravity-thermodynamics conjecture, in which the standard Bekenstein-Hawking entropy is replaced by the Barrow entropy of quantum-gravitational origin, characterized by the Barrow parameter $\Delta$. Interestingly, this framework exhibits similarities with cosmology based on Tsallis $\delta$-entropy, which, although rooted in a non-extensive generalization of Boltzmann-Gibbs statistics, features the same power-law deformation of the holographic scaling present in the Barrow case. We use observational data from Supernova Type Ia (SNIa), Cosmic Chronometers (CC), and Baryonic acoustic oscillations (BAO), including the recently released DESI DR2 data, in order to extract constraints on such scenarios. As we show, the best-fit value for the Barrow exponent $\Delta$ is found to be negative, while the zero value, which corresponds to $\Lambda$CDM paradigm, is allowed only in the range of $2\sigma $ for three out of four datasets. Additionally, for the case of the SN$_{0}$+OHD+BAO dataset, for the current Hubble function we obtain a value of $H_0= 72.2_{-0.9}^{+0.9}$, which offers an alleviation for the $H_0$ tension. Finally, by applying information criteria such as the Akaike Information Criterion and the Bayes evidence, we compare the fitting efficiency of the scenario at hand with $\Lambda$CDM cosmology, showing that the latter is slightly favoured.