Tuning Emission from Greenish to Blue via Chemical Composition Modulation in Solid Solutions (Sr1-yCay)2Sb2O7:Bi3+ under near-UV Light Excitation

The Bi3+ ion, with an exposed 6s(2) energy level sensitive for an external coordination environment, possesses complex and intriguing luminescent properties in various host lattices. Herein, we successfully prepared a new type of antimonate phosphor (Sr1-yCay)(2)Sb2O7:Bi3+ with controllable color emitting properties from greenish to blue stimulated by near-ultraviolet (UV) light. There are two emitting bands at 495 and 528 nm that go along with two crystallographic distinct Bi3+ sites in the Sr2Sb2O7 host. With increasing Ca constituents, enhancement of torsion resistance and the nephelauxetic effect would lead to the blue-shift of emitting bands. The internal quantum efficiency (IQE) of Sr2Sb2O7:0.03 Bi3+ and Ca2Sb2O7:0.03 Bi3+ was measured to be 51% and 62%, respectively. Finally, a white illuminating lamp was produced by using a 365 nm UV chip, blue phosphor Ca2Sb2O7:0.03 Bi3+, greenish phosphor Sr2Sb2O7:0.03 Bi3+, and red phosphor CaAlSiN3:Eu2+. This work can provide design insights into turning the emitting colors of Bi3+ doped phosphor by chemical composition modulation of the host lattice.

Automated summary

A new antimonate phosphor (Sr1-yCay)(2)Sb2O7:Bi3+ was successfully prepared with controllable color emitting properties from greenish to blue. The study revealed that increasing Ca constituents led to a blue-shift in emitting bands and measured the internal quantum efficiency of different phosphors. Furthermore, a white illuminating lamp was produced using a combination of UV chip, blue phosphor, greenish phosphor, and red phosphor.