Effective Control of the Ratio of Red to Green Emission in Upconverting LaF3 Nanoparticles Codoped with Yb~(3+) and Ho~(3+) Ions Embedded in a Silica Matrix

摘要

The red to green ratio from upconversion in Yb~(3+)and Ho~(3+) codoped LaF3 nanoparticles embedded in a silica matrix can be controlled by careful tuning of the sol-gel process. Red to green ratios of 1:2.3 to 23:1 were observed from the samples that had the same composition of Yb~(3+) and Ho~(3+) ions codoped LaF3 nanoparticles. The varied ratios were achieved by changing the aging and drying time of the sol-gel and the subsequent annealing process at elevated temperatures. XRD measurements showed that the sample that gave a red to green ratio of 23:1 had large amounts of amorphous silica, whereas the sample that gave a ratio of 1:2.3 had cristobalite, i.e., crystalline silica, in excess. The phonon energy of amorphous silica is higher than that of cristobalite, so quenching of the green emission effectively resulted in enhanced red emission. To prove that amorphous silica has a higher phonon energy, we completed upconversion luminescence studies at 77 K, which resulted in a decrease in the red to green ratio by a factor of 3. This indeed proves that the phonon energy of amorphous silica is the factor for observing enhanced red emission and a good control over the ratio of red to green. Infrared spectra show Si-O stretching vibrations over a broader energy range for amorphous silica than cristobalite which thus more easily matches with the difference in the energy levels of Ho~(3+) ions, making the quenching process more efficient To substantiate the above evidence, we performed partial etching of samples where enhanced red to green ratio was observed, and XRD results show the presence of amorphous silica and LaF3 nanoparticles. After nearly complete etching of the silica, XRD results show the presence of LaF3 and very little silica.