Scattering Cancellation by a Monolayer Cloak in Oxide Dispersion-Strengthened Alloys

In addition to wave-based fields, metamaterials can manipulate diffusion fields at will, for example, the scattering cancellation of particle flow in natural materials. In this paper, a monolayer cloak is proposed to eliminate electron scattering and improve the total conductivity in commonly used aluminum-oxide-dispersion-strengthened copper alloys (Cu-Al2O3) after a multiscale model is established to theoretically explain the dependence of conductivity on scattering behavior. Intense electron scattering caused by dispersed alumina nanoinclusions dominates the drastic drop in the conductivity in the Cu-Al(2)O(3)system. The Drude model is expanded to a generalized form to explain the multiscale scattering regime in Cu-Al(2)O(3)after unifying the macro- and nanoscale considerations into the mesoscopic multibody scattering process of a Monte Carlo simulation. The results indicate that the conductivity is closely related to the overall electron density and relaxation time of electrons. Then, a cloak is designed based on scattering cancellation to improve the conductivity by reducing electron collisions, whose structure is simplified into a monolayer cloak by adopting an imaginary insulating layer. Both simulation and experiment confirm a substantial improvement of the total conductivity. The invisible cloaks manipulating particle flow expands the research scope of metamaterials to innovatively improve the properties of traditional materials.