Dynamic Stabilization against Ionization in Strong-Field Regimes: Parametric Renormalization in the Kramers-Henneberger Atom

This work presents a theoretical analysis of dynamic stabilization in strong-field atomic physics using high-frequency parametric forcing. Within the Kramers-Henneberger (KH) frame, we show that the rapid quiver motion of an electron in a super-intense, high-frequency electromagnetic field induces a time-averaged renormalization of the Coulomb potential. This dynamic averaging smears the nuclear singularity, producing an effective potential with reduced depth and modified spatial structure. As a result, the coupling between bound states and the continuum is significantly reduced, leading to suppression of ionization rates in the high-frequency regime. The analysis provides a physically grounded interpretation of atomic stabilization as a consequence of parametric renormalization of the interaction potential. Connections to broader dynamic stabilization mechanisms in nonlinear systems are discussed in a cautious and qualitative manner.