Enhancing the blue luminescence behaviour of the Li co-doped novel phosphor ZnB2O4: Tm3

Enhancing the blue luminescence behaviour of the Li co-doped novel phosphor ZnB2O4: Tm3

Here we report a detailed structural analysis, and properties of the cathodoluminescence (CL), photoluminescence (PL) and 3D thermoluminescence spectra of the Tm3+ incorporated ZnB2O4 phosphor successfully synthesized through wet-chemical synthesis. The formation of a single-phase compound is verifi...

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Bibliographic Details
Published in:Journal of alloys and compounds Vol. 838; p. 155587
Main Authors: Kucuk, N., Kaynar, Ümit H., Akca, S., Alajlani, Y., Yin, L., Wang, Y., Garcia Guinea, J., Bulcar, K., Dogan, T., Karabulut, Y., Ayvacikli, M., Canimoglu, A., Topaksu, M., Can, N.
Format: Journal Article
Language:English
Published: Lausanne Elsevier B.V 15-10-2020
Elsevier BV
Subjects:
Cathodoluminescence
Charge compensation
Chemical synthesis
Electron beams
Emission analysis
Excitation
Lithium ions
Low voltage
Luminescence
Multipoles
Optoelectronic devices
Phosphors
Photoluminescence
Rare-earth
Room temperature
Structural analysis
Thermoluminescence
XRD
ZnB2O4
ZnB2O4
Charge compensation
Rare-earth
XRD
Luminescence
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Summary:Here we report a detailed structural analysis, and properties of the cathodoluminescence (CL), photoluminescence (PL) and 3D thermoluminescence spectra of the Tm3+ incorporated ZnB2O4 phosphor successfully synthesized through wet-chemical synthesis. The formation of a single-phase compound is verified through X-ray diffraction (XRD) studies. The phosphor shows an efficient blue emission located at 458 nm corresponding to 1D2→3F4 under both a low voltage electron beam and UV excitation. The optimal concentration of the doped Tm3+ is 0.5 mol% in CL and PL measurements. The corresponding concentration quenching mechanism is confirmed to be a multipole-multipole interaction, and the critical distance between Tm3+ ions is estimated to be 34 Å. Incorporating Li+ remarkably enhances the luminescence intensity probably because of the charge compensation effect. Li ions are speculated to fill the defects in the ZnB2O4 host and then the excitation energy transfers from the host to Tm3+. Surprisingly, the thermoluminescence spectra of ZnB2O4:Tm3+ and Li+ co-doped ZnB2O4:Tm3+ recorded in the temperature range 30–400 °C follow a different pattern compared with PL and CL data. The dominant signals come from Tm3+ sites. Above room temperature, the Tm3+ ions do not show the peak temperature movement, but do exhibit a different pattern with the addition of co-doped Li+ ions. These results indicate that these phosphors are promising candidates for luminescence-based optoelectronic devices. [Display omitted] •Li co-doped ZnB2O4:Tm3+ phosphors were synthesized by wet chemical method.•Structural and luminescence properties were conducted by XRD, PL, CL and 3DTL.•Luminescence enhancement was realized by charge compensation.•The effects of temperature on Tm and Li co-doped luminescence properties were also discussed.
ISSN:0925-8388
1873-4669
DOI:10.1016/j.jallcom.2020.155587