When Screening Current Controls Ferroelectric Switching: From Field-Limited to Current-Limited Regimes under an SPM Tip

Tip-induced switching in ferroelectrics is commonly framed as a field-driven process controlled by domain-wall kinetics. Here we argue for a more universal viewpoint: under a scanning probe, polarization reversal is fundamentally constrained by how fast screening charge can be supplied and redistributed. By combining local switching experiments with finite-element simulations, we identify a screening-current-limited mechanism in which charge injection and its space-charge-limited relaxation set the pace of switching and the scaling of domain growth. This framework naturally explains regime changes and the apparent breakdown of intrinsic domain-wall laws often inferred in the nanoscale piezoelectric hysteresis measurements. Beyond a reinterpretation of tip switching, the results position screening currents as a hidden control parameter of ferroelectric reversal across materials, turning current regulation into a practical handle for deterministic nanoscale domain engineering.