Crystal-field Stark effect on the upconversion light emission spectrum of alpha-NaYF4 nanoparticles doped with Dy3+, Er3+, or Yb3+

NaYF4 nanoparticles (NPs) form in two crystal structures, cubic (alpha-phase) and hexagonal (beta-phase), each one presenting a different crystal electric field (CEF) Stark effect, that affects the upconversion (UC) light emission of the NPs when doped with rare-earth elements. Therefore, the knowledge of the CEF parameters, the wave functions, and energy levels of the rare earth (RE) J-multiplet is expected to be of great help for the understanding and improvement of the UC light emission. In this work, alpha-phase NaYF4 NPs doped with Dy3+, Er3+, or Yb3+ were investigated by means of magnetization, electron spin resonance (ESR), and optical spectroscopy techniques. Fittings of the temperature-and magnetic-field-dependent magnetization were performed to determine the fourth-and sixth-order cubic CEF parameters, B4 and B6. The ground state of Er3+, Yb3+, and Dy3+ in these alpha-NaYF4 NPs was confirmed by low-temperature ESR experiments. The obtained CEF parameters were used to write down a total Hamiltonian that allows to determine the CEF Stark splitting for all energy levels of the REs 4 f unfilled shell. We give details of how the Stark effect affects the overall energy splitting of the various J-multiplets and may explain the fine structure of the UC light emission in these cubic NaY1-delta RE delta F4 NPs. (AU)