New fluorophosphate glasses co-doped with Eu super(3+) and Tb super(3+) as candidates for generating tunable visible light

• Published in: Journal of alloys and compounds Vol. 647; pp. 315 - 321
• Main Authors: de Queiroz, T B, Botelho, M BS, Goncalves, T S, Dousti, M Reza, de Camargo, A SS
• Format: Journal Article
• Language: English
• Published: 25.10.2015
• Subjects: Approximation; Emittance; Excitation; Glass; Rare earth metals; Spectroscopy; Wavelengths; White light
• ISSN: 0925-8388
• DOI: 10.1016/j.jallcom.2015.06.066

A series of optically active Eu super(3+) and Tb super(3+) doped fluorophosphate glasses with compositions (BaF sub(2)) sub(0.25)(SrF sub(2)) sub(0.25)(AlF sub(3)) sub(0.10)[Al(PO sub(3)) sub(3) sub(0.20)(YF sub(3)) sub(0.20-x)(EuF sub(3) and/or TbF sub(3)) sub(x) (x = 0 to 0.04) was prepared and characterized by optical spectroscopy. While embedded in the oxyfluoride host, the cited rare earth (RE) ions exhibit improved spectroscopic properties such as longer excited state lifetimes than in oxide glasses and intense emissions in the red ( super(5)Do [arrowright] super(7)F sub(2), Eu super(3+)), green and blue ( super(5)D sub(4) [arrowright] super(7)F sub(5) and super(5)D sub(3), super( 5)G sub(6) [arrowright] super(7)F sub(5), super( 7)F sub(4), Tb super(3+)) spectral regions. Based on this fact, co-doped samples can be designed with appropriate concentrations of these two ions and generate tunable and white light upon excitation with suitable wavelengths, dispensing the need for a third blue emitting RE ion. Four co-doped samples with equal amounts of EuF sub(3) and TbF sub(3) and total concentration of 0.3,0.5,1.0 and 1.5 mol% were tested. Their CIE chromaticity coordinates were calculated for various excitation wavelengths in the region from 350 to 360 nm allowing tuned emission from blue to red. The long lifetime values of the emitting levels in these co-doped samples ([tau] [approximate] 3.1 ms for Eu super(3+) super(5)D sub(0), and [tau] [approximate] 4.0 ms for Tb super(3+) super(5)D sub(4)), associated with fairly high quantum yields (Q.Y. = 5-12%) of the samples indicate that these materials could be efficiently pumped by high power LEDs around 355 nm.