Title :
Plasmon-enhanced non-radiative energy transfer in a hybrid quantum well structure
Author :
Higgins, L.J. ; Karanikolas, V.D. ; Murphy, G.P. ; Zhang, X. ; Marocico, C.A. ; Parbrook, P.J. ; Bradley, A.L.
Author_Institution :
Dept. of Phys. & CRANN, Trinity Coll. Dublin, Dublin, Ireland
Abstract :
Three different silver metal nanobox arrays are used to demonstrate plasmon-enhanced non-radiative energy transfer from an InGaN/GaN quantum well to a ~80 nm thick layer of CdSe/ZnS quantum dots embedded in PMMA. These arrays of varying periodicity are fabricated using helium-ion lithography. Whilst no direct signatures of non-radiative energy transfer are detected in the absence of the Ag nanobox arrays, we observe plasmon-enhanced non-radiative energy transfer efficiencies of up to 30% from the quantum well to the quantum dots. We show that by tuning the Ag nanobox array periodicity the acceptor QD emission can be optimized to benefit from both non-radiative energy transfer and direct plasmonic enhancement of the QD emission. QD emission enhancements of up to 71% were observed and QD lifetime enhancements of ~50% are also reported.
Keywords :
II-VI semiconductors; cadmium compounds; plasmons; quantum well devices; semiconductor quantum dots; semiconductor quantum wells; zinc compounds; CdSe-ZnS; PMMA; QD lifetime enhancement; acceptor QD emission; direct plasmonic enhancement; helium-ion lithography; hybrid quantum well structure; nanobox array periodicity; plasmon enhanced nonradiative energy transfer; quantum dots; silver metal nanobox array; Energy exchange; Gallium nitride; II-VI semiconductor materials; Nanostructures; Plasmons; Quantum dots; Substrates; arrayed geometries; helium-ion lithography; non-radiative energy transfer; plasmonics; quantum dot; quantum well;
Conference_Titel :
Transparent Optical Networks (ICTON), 2015 17th International Conference on
Conference_Location :
Budapest
DOI :
10.1109/ICTON.2015.7193600
