k-inflation: Non-separable case meets ACT measurements

Abstract

We investigate a non-separable subset of k-essence in which the kinetic and potential sectors interact through an XV(φ) coupling, implemented via a potential-dependent prefactor f(φ)=1+2KV. In slow roll, this structure preserves a constant sound speed cs2=1/(2-1) while modifying the Hubble flow in a controlled way, thereby shifting the inflationary observables relative to the separable template. For monomial potentials V=Aφn (with n=2 and n=2/3 as representative cases) we derive closed analytic expressions for ns(N) and r(N) to O(ε mix2), where ε mix encodes the non-separable X V mixing, and we validate them against exact background integrations. The analytic and numerical predictions agree at the sub-per-mille level for ns and at the percent level for r, confirming the accuracy of the small-mixing expansion. For K<0 the mixing systematically lowers both ns and r at fixed N, allowing otherwise marginal monomials to fall within the region favored by recent ACT+ Planck+BAO constraints (P--ACT--LB). All solutions shown satisfy the health conditions f(φ)>0, >12, and the positivity bound V<1/(2| K|) (from f>0). We also discuss parameter dependence and the expected equilateral-type non-Gaussianity, which remains comfortably within current bounds for the benchmarks considered.

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