Why $w \ne -1$? Anthropic Selection in a $Λ$ + Axion Dark Energy Model
Abstract
We study a dark energy model composed of a bare negative cosmological constant and a single ultra-light axion, motivated by the string axiverse. Assuming that intelligent observers can exist and observe an accelerating universe, we derive nontrivial constraints on both the axion mass and the bare cosmological constant. The axion mass is bounded from above to avoid fine-tuning of the initial misalignment angle near the hilltop, and from below because extremely light axions would require the bare cosmological constant to be unnaturally close to zero to achieve accelerated expansion. As a result, the anthropically allowed axion mass range typically lies around $m = \mathcal{O}(10)\, H_0$ for a decay constant close to the Planck scale, where $H_0$ is the observed value of the Hubble constant. In this framework, the dark energy equation of state parameter $w_0$ generically deviates from $-1$ by $\mathcal{O}(0.1)$, providing a natural explanation for why $w \ne -1$ may be expected. This outcome is intriguingly consistent with recent DESI hints of time-varying dark energy, and offers a compelling anthropic explanation within the $\Lambda$ + axion framework.