Dimers made of noble metal particles possess extraordinary field enhancements but suffer from large dissipation, whereas low-loss dielectric dimers are limited by relatively weak optical confinement. Hybrid Systems could take advantages from both worlds. In this contribution, we,study the mode coupling in a hybrid' dimer with rigorous dipole dipole interaction theory and expiate its potential in fluorescence enhancement. We first discovered that the,direct coupling between metal surface plasmon resonance and dielectric electric dipole mode (mates a hybridized mode due to the strong electric electric dipole dipole interaction between the constituent nanoparticles, whereas. the dielectric magnetic dipole mode can only indirectly couple to the, plasmons on the basis of the induced electric magnetic dipole dipole interaction. When an electric/magnetic quantum emitter couples to the hybrid dimer, the emitter selectively excites the electric/magnetic (magnetic/electric) resonant modes of the dirtier for; emitter orientation parallel (perpendicular) to the dimer axis. Our study shows that the hybrid dimer simultaneously possesses high field enhancement and low-loss features, which demonstrates a fluorescence excitation rate 40% higher than that of the pure dielectric airier and an average quantum yield 30% higher, than that of the pure metallic dimer.: On top of that, the unique asymmetrical structure of the hybrid dimer directs 20% more radiation toward the diectric side, hence improving the directivity of the dimer as an antenna.

• 出版日期2017-6-15
• 单位中国工程物理研究院; 武汉理工大学