采用基于磁控等离子体团簇束流源的低能团簇束流沉积在石英衬底上制备了银纳米团簇颗粒,并测量了其透射光谱.将二氧化硅荧光纳米球分别分散在裸石英片和有银纳米团簇颗粒的石英片上,用波长为410 nm的激光激发,结果表明有银钠米团簇颗粒的荧光发射强度与没有银纳米团簇颗粒的荧光发射强度相比,增强倍数达5.3倍.最后,用Mie散射理论数值计算单个银纳米球颗粒在其表面等离激元共振位置处的电场强度分布,据此对实验结果进行了合理的解释.
Using low energy cluster beam deposition based on magnetron plasma gas aggregation cluster source, we fabricated silver nanoclusters on a quartz substrate and measured its transmittance spectrum. Then we dispersed SiO2 fluorescent nanospheres separately on bare quartz substrates and quartz substrates with silver nanoclusters. We found that the fluorescence intensity with silver nanoclusters was 5.3 larger than that without silver nanoclusters. Finally, we used the Mie scattering theory to numerically calculate the electric field intensity distributions of a single silver nanosphere where surface plasmon resonance existed. We give a reasonable explanation for the experimental results.
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