Atomistic Theory of Plasmon-Induced Hot-carriers in Al Nanoparticles

Abstract: Hot electrons generated from the decay of localized surface plasmon (LSP) in metallic nanostructures have significant potential for applications in photocatalysis, photodetection, and other optoelectronic devices. Aluminum nanoparticles are promising for hot-carrier devices since aluminum is the third most abundant element in the Earth's crust. However, a comprehensive understanding of hot-carrier generation in practical nanoparticles is still missing. In this study, we present theoretical predictions of hot-carrier generation rates in spherical aluminum nanoparticles with up to 315,75 atoms in different dielectric environments. These predictions are obtained from an approach, which combines a solution of Maxwell equation with large-scale atomistic tight-binding models. By changing the environmental dielectric constants, the LSP frequency can be adjusted over a wide range from deep ultraviolet at 9 eV to the visible spectrum at 2-2.75 eV. Meanwhile, by varying the sizes of nanoparticles, we observed that as the nanoparticle size increases to 10 nm, discrete hot-carrier energy level transitions converge to the continuous energy transitions of bulk metals, and no intraband transitions are observed, unlike in noble metal nanoparticles such as gold and silver.