Coupled Dark Energy and Dark Matter for DESI: An Effective Guide to the Phantom Divide

Abstract

Motivated by the recent Dark Energy Spectroscopic Instrument (DESI) DR2 preference for dynamical dark energy, we study interacting dark energy models in which a canonical quintessence field couples to cold dark matter through a field-dependent mass m(φ). In such scenarios, the effective equation of state inferred under the assumption of non-interacting dark sectors, w eff(z), can differ from the intrinsic scalar-field equation of state wφ(z), making an apparent phantom crossing w eff<-1 possible without introducing a phantom scalar. We show that a viable realization of this mechanism requires the scalar field to originate from a frozen phase deep in the radiation era, in order for the effective coupling to remain sufficiently suppressed before recombination to evade cosmic microwave background constraints, and for the late-time evolution to become strong enough to reproduce the apparent behavior of w eff(z) preferred by DESI. We identify the general conditions that allow these requirements to be satisfied simultaneously, and present an illustrative phenomenological realization in which w eff(z) evolves from w eff≈ -1.2 at z ≈ 1.0 to w eff≈ -0.9 at z≈ 0.4. These conditions and requirements serve as a guide for designing future models of this kind which can safely navigate the phantom divide at w=-1 in an effective way without phantom fields.