Abstract
In 1946, Purcell proposed that integrating emitters into a resonant cavity can electromagnetically modify the local density of states (LDOS), thus affecting emitters' absorption and/or emission rates. This effect has been considered as the "standard answer" to explain emission modification, laying theoretical foundation for numerous applications. Here we report that for the interaction between semiconducting emitters and plasmonic resonators, Purcell effect cannot fully explain the modification of emitters' relaxation dynamics, in which plasmonic doping of hot electrons also plays a critical role. Specifically, by integrating quantum dots (QDs) into a grating-like plasmonic resonator, we can dope QDs with hot electrons that are produced during plasmon excitation. This makes excited carriers outnumber the absorbed photons, forming an asymmetric excitation in QDs. These carriers accumulate in the conduction band of the QDs, resulting a radiative emission at higher energy which cannot be enabled by LDOS modification and is hence beyond the explanation of Purcell effect. Our findings identify a new cavity-emitter interaction pathway, providing novel schemes for both fundamental studies, e.g. quantum electrodynamics, and practical applications, e.g. gain provision
*The authors acknowledge the New Idea Research Funding 2018 (Dodd-Walls Centre for photonic and quantum technologies), the Marsden Fast-start Fund by Royal Society of New Zealand through contract MFP-UOO1827 and MFP-VUW1715 and the Smart Ideas Fund by Ministry of Business, Innovation and Employment, New Zealand through contract UOOX1802. In addition, this work was supported in part by the National Key Research and Development Program of China (No. 2017YFA0205700) and the National Natural Science Foundation of China (Nos. 6192782 and 51861135201), Beijing Municipal Natural Science Foundation (1214027), the Science and Technology Innovation Project of Beijing Institute of Technology and the NSFC funding (12004313).
