UVB upconversion of LiYO2:Ho3+,Gd3+ for application in luminescence thermometry

Abstract

Development of novel ultraviolet (UV) upconversion materials has been emerging as a hot research topic for application in tunable UV lasers, photocatalysis, sterilization, tagging, and most recently luminescence thermometry. We readily synthesized a series of Ho³⁺/Gd³⁺ co-doped LiYO₂ upconversion phosphors by a traditional high-temperature reaction. Under excitation from a blue ∼445 nm laser, LiYO₂:Ho³⁺,Gd³⁺ polycrystalline powders yield intense sharp ultraviolet B (UVB) upconversion luminescence from Gd^{3+ 6}P_j (j = 7/2, 5/2, 3/2) excited states. By means of steady and dynamic photoluminescence spectra, we systematically investigated the involved two-photon absorption upconversion as well as the accompanying energy transfer processes between Ho³⁺ and Gd³⁺ ions in the LiYO₂ host lattice. Interestingly, the distinguishable UVB luminescence constituents from Gd^{3+ 6}P_j excited states exhibit sensitive temperature dependence in a 353–673 K range. Shedding light on thermal equilibria between Gd^{3+ 6}P_j UV-emitting levels, their luminescence intensity ratios follow Boltzmann statistics for the application of new luminescence thermometry. For the scheme of ⁶P_7/2–⁶P_3/2 thermally coupled levels, it works over a temperature range of 373–673 K with a maximum relative sensitivity (S_r) of about 1.07% K⁻¹ at 373 K, and its ⁶P_7/2–⁶P_5/2 counterpart works over 353–533 K with a maximum S_r of about 0.83% K⁻¹ at 353 K. Overall, our study provides a new pathway to develop UV upconversion materials, and promotes the application of Gd³⁺-related UV luminescence constituents in sensitive temperature sensing over a wide temperature range.