Thermal Stability of Gold Nanorods for High-Temperature Plasmonic Sensing

There are many potential sensing applications for Au nanorods due to a tunable localized surface plasmon resonance (LSPR) frequency that changes with aspect ratio. However, their application at high temperatures is limited due to a shape change that can take place well below the melting point of bulk Au, driven by a reduction in surface energy. A method of stabilizing Au nanorods is provided here by encapsulating them with a 15 nm capping layer of yttria stabilized zirconia (YSZ). After annealing rods with nominal dimensions of 100 × 44 nm to a temperature of 600 °C, small reductions in length were observed, but the rods remained stable for all subsequent sensing tests at 500 °C, which amounted to 80 h. It was shown with a separate sample that the rod geometry can be preserved even up to 800 °C over a 12 h annealing period, although a significant shortening of the rod length occurred, leaving a void space in the YSZ. The sensing response of both the transverse and the longitudinal LSPR peaks was monitored for H₂, CO, and NO₂ exposures in an air background at 500 °C. In all cases, the longitudinal LSPR peak shows a larger shift upon gas exposure than does the transverse peak