Excellent thermal stability of Y2.94Al4-xSixGaO12: 0.06Ce3+ phosphor for optical storage

In order to prepare various Y2.94Al4-xSixGaO12: 0.06Ce(3+) phosphors, a traditional approach to solid-state reaction was adopted. XRD and Rietveld were refined to confirm the cubic garnet crystal structure of phosphors. Besides, the substance displayed a wide mission band varying between 475 nm and 650 nm due to the 5d -> 4f transitions of the Ce3+ ions as excited by a 450 nm wavelength. Furthermore, as the Si4+ concentration increases from 0 to 0.6, we can observe a blue shift in the emission spectrum from 510 nm to 502 nm. The emission intensity at 453 K is still 88% of that at room temperature. At the same time, through the auxiliary calculation of activation energy, the advantages of thermal stability and the weakness of thermal quenching are explained. Surprisingly, a demonstrational application confirmed the excellent capability of optical data retention in encoding/decoding the material, including a designed bar code and graphic patterns. It is suggested that phosphor is applicable for the development of white LEDs based on the blue LED-chip. In particular, when some unexpected circumstances occur and lighting conditions suddenly break down, LED with long afterglow performance can alleviate the discomfort caused by the change. It is also expected to move forward the study on Long-lasting phosphorescence (LLP) materials and their practical application in optical storage. (C) 2021 Published by Elsevier B.V.

Automated summary

The study prepared various Y2.94Al4-xSixGaO12:0.06Ce(3+) phosphors using a traditional solid-state reaction method, confirming their cubic garnet crystal structure through XRD and Rietveld refinement. The broad emission band from 475 nm to 650 nm was observed due to the 5d -> 4f transitions of Ce3+ ions, with a blue shift in the emission spectrum as the Si4+ concentration increased. The study also explained the advantages of thermal stability and the weakness of thermal quenching through activation energy calculations.