Energy-Resolved Femtosecond Hot Electron Dynamics in Single Plasmonic Nanoparticles

Abstract

Efficient excitation and harvesting of hot carriers are central to a variety of emerging nanoplasmonic applications, but ballistic carrier extraction remains a challenge. To elucidate the relevant dynamics as a function of nanoscale geometry, we perform femtosecond two-color pump-probe photoemission studies of single gold nanorods and gold/silica nanoshells with simultaneous time, energy, and vector momentum resolution. Angle-resolved photoelectron momentum distributions elucidate the dominant intraband photoexcitation mechanism and subsequent ballistic dynamics within the gold nanoparticle volume, as verified via Monte Carlo photoemission modeling. Energy-averaged hot electron lifetimes around 30 fs are measured in the ~1-2 eV excitation energy range, while energy-resolved measurements reveal good agreement with Fermi liquid theory behavior based on electron-electron inelastic scattering, as well as more detailed kinetic Boltzmann modeling including the effects of electron cascading from higher energy levels and quasi-elastic electron phonon scattering. These results directly demonstrate the predominance of bulk-like hot electron dynamical behaviors (including volume-like excitation and bulk inelastic scattering rates) in metal nanoparticles with dimensions as small as 10 nm, which should contribute to the design of more efficient hot carrier devices