Photonic Effects for Magnetic Dipole Transitions

[Image: see text] The radiative transition probability is a fundamental property for optical transitions. Extensive research, theoretical and experimental, has been conducted to establish the relation between the photonic environment and electric dipole (ED) transition probabilities. Recent work shows that the nanocrystal (NC)-cavity model accurately describes the influence of the refractive index n on ED transition rates for emitters in NCs. For magnetic dipole (MD) transitions, theory predicts a simple n(3) dependence. However, experimental evidence is sparse and difficult to obtain. Here we report Eu(3+)-(with distinct ED+MD transitions) and Gd(3+)-(MD transitions) doped β-NaYF(4) NC model systems to probe the influence of n on ED and MD transition probabilities through luminescence lifetime and ED/MD intensity ratio measurements. The results provide strong experimental evidence for an n(3) dependence of MD transition probabilities. This insight is important for understanding and controlling the variation of spectral distribution in emission spectra by photonic effects.