Spectral manipulation from green to red by doping Ce3+ in Ba4Y3F17:Yb3+, Ho3+ nanoparticles embedded in glass-ceramics

Spectral engineering for luminescence materials, referring to the purposeful design and modulation of luminescence properties, such as tuning of luminescence intensity and color, is extremely crucial in improving luminescence performance and extending optical applications. In this work, Yb3+-Ho3+-Ce3+ tri-doped Ba4Y3F17 nanoparticles precipitated in transparent glass-ceramics were successfully fabricated via a melt-quenching method. X-ray diffraction and transmission electron microscopy were used for characterizing the morphology, particle size, and crystal structure of samples. Low probability of multi-phonon non-radiative relaxation and incorporation of rare earth ion into Ba4Y3F17 crystalline lattice with low phonon energy result in pronounced enhancement of upconversion emission and longer lifetimes with excitation of a 980-nm laser. Introduction of Ce3+ ions can modulate emission color from green to yellow and finally to red. Detailed emission kinetics, rising time, and pump power dependency were analyzed for proposing and understanding the possible energy transfer mechanisms.

Automated summary

Spectral engineering for luminescence materials, which involves the purposeful design and modulation of luminescence properties, is crucial for improving luminescence performance and extending optical applications. In this study, Yb3+-Ho3+-Ce3+ tri-doped Ba4Y3F17 nanoparticles were successfully fabricated in transparent glass-ceramics, demonstrating enhanced upconversion emission and longer lifetimes. Introduction of Ce3+ ions enabled the modulation of emission color and provided insights into energy transfer mechanisms.