This work extends a previous investigation on plasmon enhanced optical gain in Nd 3+ doped TeO 2 -ZnO (TZ) pedestal waveguides incorporating gold nanoparticles (Au NPs) for applications at 1064 nm. The influence of Nd 3+ concentration and the role of a SiO 2 spacer layer on the plasmon assisted optical gain of Nd 3+ doped TZ were investigated. Thin films were deposited by RF magnetron sputtering, with the Nd 3+ concentration controlled by varying the number of Nd 2 O 3 pellets (1, 2, and 3). Pedestal waveguides with heights of ∼3.6 μm and widths ranging from 4 to 40 μm were characterized. Optical gain measurements at 1064 nm under 808 nm excitation showed that the lowest Nd 2 O 3 concentration achieved the highest relative gain (G R ) with enhancement of up to ∼80% due to Au NPs. Although higher Nd 3+ concentrations led to smaller improvements, attributed to self-absorption and non-radiative losses, the positive role of Au-NPs was observed. The introduction of SiO 2 spacer layers (25 or 100 nm) between the active core and Au NPs completely suppressed the plasmonic enhancement, confirming the importance of adequate distances between the rare-earth ions and the metallic NPs. These findings highlights the critical roles of dopant concentration and nanoscale Au NPs-core separation in maximizing plasmon assisted G R in Nd 3+ doped TZ based waveguides, providing guidance for the design of compact and efficient on-chip optical amplifiers. • Plasmon-assisted optical gain strongly depends on Nd 3+ concentration • Au nanoparticles deposited directly on the core: gain growth of up to ∼80% at 1064 nm • Optimal performance for the lowest Nd 3+ concentration: gain of up to 11 dB/cm • Au nanoparticles and the active core distance: relevance to promote plasmonic effects • Higher Nd 3+ concentrations reduce waveguide performance
Kumada et al. (Sun,) studied this question.