Anomalous stopping of laser-accelerated intense proton beam in dense ionized matter

Ultrahigh-intensity lasers (10$^{18}$-10$^{22}$W/cm$^{2}$) have opened up new perspectives in many fields of research and application. By irradiating a thin foil, an ultrahigh accelerating field (10$^{12}$ V/m) can be formed and multi-MeV ions with unprecedentedly high intensity (10$^{10}$A/cm$^2$) in short time scale. Such beams provide new options in radiography, high-yield neutron sources, high-energy-density-matter generation, and ion fast ignition. An accurate understanding of the nonlinear behavior during the beam transportation in matter is crucial for all these applications. We report here the first experimental evidence of anomalous stopping of laser-generated high-current proton beam in well-characterized dense ionized matter. The observed stopping power is one order of magnitude higher than single-particle slowing-down theory predictions. We attribute this phenomenon to a collective effect that the intense beam drives an decelerating electric field approaching 10${^9}$ V/m in the dense ionized matter. This finding will have considerable impact on the future path to inertial fusion energy.