Generalizing the interacting dilatonic ghost condensate as a dark energy model

Abstract

In this article, we study the cosmic evolution of a generalized dilatonic ghost condensate field as a dark energy candidate, formulated from a Lagrangian density with two dominant kinetic terms; one linear and one of arbitrary integer n>2 in combination with an exponential potential, which interacts with dark matter through a source term. We analyzed three scenarios: the non-interacting situation Q=0 and two different interaction models, Qρmϕ and Q ρm H to describe the evolution of the present universe. For each interaction Q, we perform a detailed phase-space analysis to obtain stability conditions and identify critical points. In all situations, the system reproduces the standard cosmological dynamics and evolves toward late-time dark energy-dominated attractors, with quintessence or phantom features depending on the sign of the coupling parameter α associated with the standard kinetic term. Furthermore, a joint likelihood analysis with Cosmic Chronometers, PantheonPlus, and DESI observations is performed for two values of power n (n=3 and n=5) to determine marginalized parameter constraints at the confidence levels of 68\% and 95\% for the different Q-models. For the interaction term Q ϕρm, we find that the direction of the flow of energy depends on the sign of the coupling parameter α associated with the standard kinetic term. However, for the interaction Q H\,ρm, the direction of the energy flow is independent of the sign of the coupling parameter α and always remains negative, corresponding to an energy transfer from dark matter to dark energy.