Light-Driven Bound State of Interacting Impurities in a Dirac-Like Bath

Recent investigations have revealed the presence of exceptional points in the low-energy effective spin-interacting impurity model, previously explored via non-Hermitian renormalization group (RG) techniques. These studies uncovered novel RG fixed points and linked them to distinct transport signatures. In this work, we revisit the model from a real-time field-theoretic perspective, studying both non-interacting and strongly correlated ($U = \infty$) limits using the exact equation of motion and a Large-$N$ Keldysh variational mean-field approach. Remarkably, we find that the steady-state solutions of the Keldysh action exhibit the same fixed point structure as the RG flows, independently recovering the exceptional behavior. Our analysis further reveals that exceptional points (EPs) arise naturally in the Green's function structure without any ad hoc non-Hermitian terms and are associated with self-consistent light-induced hybridization in specific regimes. Importantly, we identify a new causal steady state in which the appearance of EPs is not inherently tied to causality violation; instead, a sign-reversing (negative) flip hybridization contribution restores causality. These findings suggest a broader framework in which EPs coexist with well-defined dynamical behavior and open the door to controlled light-driven engineering of dissipative quantum impurity states.