Abstract
The plasmonic enhancement or quenching effects of a silica-coated gold nanorod (GNR@SiO 2) on the fluorescence of a molecule doped in the silica layer are studied using the multiple multipole method. The enhancement factors (EF) of a GNR with a typical aspect ratio of 3 coated by a 13nm silica layer upon the fluorescence of a molecule embedded at different locations with various orientations irradiated by a plane wave are analyzed, particularly at the longitudinal surface plasmon resonance (SPR) of GNR. The numerical results show that the EF of a GNR@SiO 2 on the fluorescence is sensitive to the molecular location and orientation. Furthermore, an effective EF (EEF), which is an average of EF over all possible orientations at a specific location, is calculated. According to EEF, the proximities of the end-caps of a GNR are strong enhancing zones. In contrast, the waist area is the weak zone. Moreover, a bigger GNR (a=10nm) possesses a higher EEF than a smaller one (a=7nm) for the same aspect ratio and the molecular relative location. Hence, a strong enhancement on the fluorescence is obtained using bigger GNR, if the molecule is near the end-cup and the dipole orientation is along the long axis. On the contrary, the consequence could be quenching, if the molecule is near the waist of a small GNR. The Stokes shift of fluorescence can also affect the EF, except the excitation wavelength.
Original language | English |
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Pages (from-to) | 470-479 |
Number of pages | 10 |
Journal | Journal of Quantitative Spectroscopy and Radiative Transfer |
Volume | 113 |
Issue number | 6 |
DOIs | |
State | Published - 04 2012 |
Keywords
- Enhancement factor
- Fluorescence
- Longitudinal surface plasmon resonance
- Plasmonic enhancement
- Quenching
- Silica-coated gold nanorod
- Surface enhanced fluorescence