Ultrafast electron dynamics studied with time-resolved two-photon photoemission: Intra- and interband scattering in C 6F 6/Cu(111)

Abstract

The advances in femtosecond laser techniques facilitate the investigation of ultrafast electron dynamics at surfaces directly in the time-domain. We employ time-resolved two-photon-photoemission (2PPE) spectroscopy to study the electron dynamics of the unoccupied electronic states in hexafluorobenzene (C 6F 6) on Cu(111) serving as a model system for charge transfer across organic-metal interfaces. Our coverage-dependent study reveals a lifetime of the lowest unoccupied molecular resonance of 7 fs for a single monolayer (ML) which increases to 37 fs above 3 ML coverage. We find that the population build-up of the excited state is delayed by a characteristic time of about 10fs with respect to the exciting laser pulse. By angle-resolved 2PPE spectroscopy, the mechanism of the delayed population rise is identified as intraband relaxation in the adsorbate band structure. The actual electron-transfer to the metal substrate occurs through interband scattering between the molecular resonance and substrate states on comparable timescales. Therefore the present study demonstrates that relaxation of hot electrons at molecule-metal interfaces include - even in the presence of strong electronic molecule-substrate interaction - also decay channels within the adlayer. © IOP Publishing Ltd and Deutsche Physikalische Gesellschaft.