Plasmon-powered upconversion nanocrystals for enhanced bioimaging and polarized emission

In this work, we propose to employ the double plasmon resonances of a silica-coated gold nanorod to enhance the upconversion luminescence intensity of CaF2:Yb3+,Er3+ nanocrystals and simultaneously modulate the polarization state of the red and green emissions. We have successfully synthesized hybrid plasmonic upconversion nanostructures consisting of sub-10 nm CaF2:Yb3+,Er3+ UCNCs attached on silica-coated gold nanorods in a core-shell-satellite geometry. By precisely tuning the thickness of silica shell, we have achieved a maximum luminescence enhancement factor of ~7-fold for the red emission band and ~3-fold for the green emission band. With the enhanced upconversion emissions, such hybrid plasmonic upconversion nanostructures exhibit better multiphoton imaging contrast of HeLa cells in both red and green imaging channels, demonstrating their use as a promising nonlinear fluorescent probe for high-contrast bioimaging applications. More interestingly, we have observed that the two emissions from single hybrid nanostructures are highly polarized with distinctive polarization response, with the red emission polarization along the long axis of the gold nanorod and the green emission polarization along the incidence polarization. We have analyzed the physical origin responsible for the polarized upconversion emissions by combining Förster resonance energy transfer theory and full-wave electrodynamic simulations. We have found that the coherent interaction between the emission dipoles of UCNCs and the plasmonic dipoles of the GNR determines the emission polarization state in various situations and thus open the way to the accurate control of the UC emission anisotropy for a wide range of bioimaging and biosensing applications as well as polarized illuminators in spectrometers and polarization-sensitive nanoscale photodetectors.

The related work has been published in Light: Science & Applications.