Cosmological constraints on mass-varying dark matter

Light mass warm dark matter is an interesting and viable alternative to the cold dark matter paradigm. An intriguing variation of this scenario is the mass-varying dark matter model where the dark matter mass varies with time during its cosmic history. This is realized in multiple particle physics models. In this work, we study the cosmological constraints on such a model where the dark matter mass transitions from zero to a finite value in the early Universe. In this model, the matter power spectrum exhibits power suppression below a scale that depends on the epoch of transition, and the angular power spectrum of the cosmic microwave background show a distinctive phase shift. We use the latest cosmic microwave background and the weak lensing data to place lower limit on the transition redshift and ease the $S_8$ tension, unlike the warm dark matter model. This analysis also facilitates a marginal detection of the dark matter (DM) mass. Our findings reveal that while Planck data alone reduces the $S_8$ tension to approximately $2\sigma$, it does not sufficiently constrain the DM mass. However, when combined with the $S_8$ measurement from KIDS1000+BOSS+2dfLenS, the tension significantly decreases to roughly $1.3\sigma$, and we observe the detection of a DM mass at $41.7^{+7.81}_{-27.5}\,\mathrm{eV}$. Further analysis incorporating a combined data set from ACT and weak lensing results in an even more pronounced reduction in the tension to approximately $0.4\sigma$, alongside a higher detected mass of $51.2^{+16}_{-33.5}\,\mathrm{eV}$. We also find a better fit to the combined data compared to the $\Lambda$CDM model.