Luminescence properties of Eu 3+ doped YBO 3 for temperature sensing

Multisignal optical temperature-sensing properties of Eu3+ -doped NaYF4 nanoparticles

In this paper, the multisignal (different emissions/colours) temperature sensing of NaYF4 :Eu3+ nanoparticles is investigated, which is based on fluorescence intensity ratios (FIRs) between 5 D0 →7 FJ (J=1-4) and 5 D1 →7 FJ' emissions. The 5 D1 →7 FJ' (J'=0-2) emissions can be clearly observed due to the low photon energy of NaYF4 . Based on the FIRs between different 5 D0 →7 FJ and 5 D1 →7 FJ' emissions, higher absolute/relative temperature sensitivities are obtained. Compared with the FIR between whole 5 D0 →7 FJ and 5 D1 →7 FJ' emissions, the maximum value of Sa was improved from 0.27 K-1 to 5.02 K-1 and that of Sr was improved from 0.89%·K-1 to 1.27%·K-1 . Furthermore, the FIRs between different colours of emissions were investigated for the application of wide-range multicolour temperature sensing.

Crystallization Mechanism and Optical Properties of Antimony-Germanate-Silicate Glass-Ceramic Doped with Europium Ions

Glass-ceramic is semi-novel material with many applications, but it is still problematic in obtaining fibers. This paper aims to develop a new glass-ceramic material that is a compromise between crystallization, thermal stability, and optical properties required for optical fiber technology. This compromise is made possible by an alternative method with a controlled crystallization process and a suitable choice of the chemical composition of the core material. In this way, the annealing process is eliminated, and the core material adopts a glass-ceramic character with high transparency directly in the drawing process. In the experiment, low phonon antimony-germanate-silicate glass (SGS) doped with Eu³⁺ ions and different concentrations of P₂O₅ were fabricated. The glass material crystallized during the cooling process under conditions similar to the drawing processes'. Thermal stability (DSC), X-ray photo analysis (XRD), and spectroscopic were measured. Eu³⁺ ions were used as spectral probes to determine the effect of P₂O₅ on the asymmetry ratio for the selected transitions (⁵D₀ → ⁷F₁ and ⁵D₀ → ⁷F₂). From the measurements, it was observed that the material produced exhibited amorphous or glass-ceramic properties, strongly dependent on the nucleator concentration. In addition, the conducted study confirmed that europium ions co-form the EuPO₄ structure during the cooling process from 730 °C to room temperature. Moreover, the asymmetry ratio was changed from over 4 to under 1. The result obtained confirms that the developed material has properties typical of transparent glass-ceramic while maintaining high thermal stability, which will enable the fabrication of fibers with the glass-ceramic core.

Cr3+-doped InTaO4 phosphor for multi-mode temperature sensing with high sensitivity in physiological temperature range

With the increasing demand for non-contact temperature sensing, the development of optical thermometer with excellent performance is more and more compelling. Cr3+-doped InTaO4 phosphor was prepared for the implementation of...

Photoluminescence properties, Judd-Ofelt analysis, and optical temperature sensing of Eu3+-doped Ca3La7(SiO4)5(PO4)O2 luminescent materials

A series of Eu³⁺-doped Ca₃La₇(SiO₄)₅(PO₄)O₂ (CLSPO) multifunctional phosphors were synthesized by a high-temperature solid-state reaction method. The crystal structure of the CLSPO host was explored using Rietveld refinement. The photoluminescence properties of CLSPO: Eu³⁺ phosphors were investigated systematically. Upon 392 nm near-ultraviolet light excitation, the phosphor exhibited strong characteristic emissions of Eu³⁺ ions with a dominant red emission peak around 613 nm, indicating its potential use in solid-state lighting. Calculations of Ω₂ and Ω₄ Judde-Ofelt intensity parameters provided insight into the structure-luminescence correlation in the CLSPO: Eu³⁺ system. By exploring the temperature sensitivity of photoluminescence intensity, the application potential of the sample to optical thermometry was studied.

Structural analysis and optical temperature sensing performance of Eu3+-doped Ba3In(PO4)3

Eu³⁺-Doped Ba₃In(PO₄)₃ was synthesized through a high-temperature solid-phase method.

Structural and spectroscopic properties of LaAlBO3 doped with Eu3+ ions

In this study, we performed X-ray diffraction (XRD) and environmental scanning electron microscope (ESEM) techniques to examine the structure and morphological observation of the samples and thermoluminescence (TL) experiments to extract the trapping parameters and dosimetric properties of LaAlBO₃ phosphors doped with Eu at various doping concentrations. Diffraction patterns of obtained sample were well consistent JCPDS card No 98-009-7945, indicating the formation of pure phase. The TL kinetic parameters were estimated by CGCD software. TL glow curves of LaAlBO₃:Eu³⁺ consist of 12 trap levels and exhibited dominantly first order kinetics. Photoluminescence (PL) emission was observed in the range 400-800 nm for LaAlBO₃ phosphor doped with Eu³⁺. The dominant emission of Eu³⁺ corresponding to the electric dipole transition ⁵D₀ → ⁷F₂ is located at 616 nm. The sharp emission properties exhibited demonstrate that the LaAlBO₃ is a suitable host for rare-earth ion doped phosphor material. It is observed that for the variable concentration of Eu³⁺ on PL studies, the PL intensity augments with increase in the dopant concentration and the concentration quenching was found after 1 mass% of Eu³⁺. The PL experimental results reveal that LaAlBO₃:Eu³⁺ phosphor as an red emitting phosphor may be promising luminescence materials for the optoelectronic applications.

Realizing emission color tuning, ratiometric optical thermometry and temperature-induced redshift investigation in novel Eu3+-doped Ba3La(VO4)3 phosphors

Eu³⁺ doped Ba₃La(VO₄)₃ phosphors with tunable emitting colors were firstly explored and their photoluminescence properties were investigated.

Extending the temperature sensing range using Eu3+ luminescence up to 865 K in a single crystal of EuPO4

Extending the temperature sensing range up to 865 K using an appropriate choice of excitation wavelength and coupling scheme in a single crystal sample of EuPO₄.