1. Plasmonically enhanced upconversion of 1500 nm light via trivalent Er in a TiO2 matrix
- Author
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Arne Nylandsted Larsen, Brian Julsgaard, Bjarke R. Jeppesen, Emil H. Eriksen, Joakim Vester-Petersen, Harish Lakhotiya, Jeppe Christiansen, Sabrina R. Johannsen, Adnan Nazir, Søren Madsen, and Peter Balling
- Subjects
010302 applied physics ,Materials science ,Physics and Astronomy (miscellaneous) ,business.industry ,Doping ,Physics::Optics ,Resonance ,02 engineering and technology ,021001 nanoscience & nanotechnology ,01 natural sciences ,Photon upconversion ,Red shift ,0103 physical sciences ,Optoelectronics ,Thin film ,0210 nano-technology ,Luminescence ,business ,Lithography ,Nanodisc - Abstract
In this letter, we present a comparative experimental–simulation study of Au-nanodisc-enhanced upconversion of 1500 nm light in an Er3+ doped TiO2 thin film. The geometry of the Au nanodiscs was guided by finite-element simulations based on a single nanodisc in a finite computational domain and controlled experimentally using electron-beam lithography. The surface-plasmon resonances (SPRs) exhibited a well-known spectral red shift with increasing diameter, well explained by the model. However, an experimentally observed double-peak SPR, which resulted from inter-particle interactions, was expectedly not captured by the single-particle model. At resonance, the model predicted a local-field enhancement of the upconversion yield, and experimentally, the luminescence measurements showed such enhancement up to nearly 7 fold from a nanodisc with 315 nm diameter and 50 nm height. The upconversion enhancement agreed qualitatively with the theoretical predictions, however with 3–5 times higher enhancement, which w...
- Published
- 2016
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