Late-Transition Interacting Thawer Dark Energy: Model Definition and Benchmark Consistency Tests

Abstract

We formulate the late-transition interacting thawer (LTIT) as a late-activating, variable-coupling realization of coupled quintessence in which a canonical scalar field couples conformally only to cold dark matter. The construction is a non-universal dark-sector interaction: baryons and radiation remain minimally coupled, while CDM follows a conformally related metric. This structure ties three observational sectors to one microscopic mechanism--the pre-recombination calibration scale, the low-redshift expansion history, and the coupled growth response. We derive the exact background equations, the exact CDM scaling identity (a)=ρc0a-3C[ϕ(a)]/C(ϕ0), and the coupled CDM--scalar perturbation equations in synchronous gauge in a form suitable for Einstein--Boltzmann solvers. In the representative benchmarks, Ωϕ(z*)10-9, |Δrd/rd|3.82×10-3, and 0<z<3|E/EΛCDM-1|0.380\%, while the quasi-static growth indicator ranges from 0.725\% to 5.94\%. LTIT therefore demonstrates how late activation can preserve the early calibration sector while producing a perturbation-sensitive signature, providing a concrete target for Boltzmann-level tests of interacting dark energy.