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Engineering a single phosphor for multiple objectives is challenging and essential for innovative technology, enriching productivity and flexibility, lowering cost, minimizing power intake, etc. In this study, a Yb 3+ ,Er 3+ -activated NaBiF 4 nanophosphor synthesized via a thermolysis approach provided significant opportunity to explore the potential of single phosphor in diverse fields including contactless thermometry, plasmonenhanced upconversion luminescence (UCL), solid-state lighting, and photoswitching probes. The phosphor has been characterized using several standard techniques to unveil the phase, crystal structure, associated functional groups, morphology, crystalline nature, and optical properties. A 5-fold enhancement in UCL intensity was observed from Yb 3+ ,Er 3+ :NaBiF 4 @SiO 2 @Ag. Upconversion luminescence thermometry of Yb 3+ ,Er 3+ :NaBiF 4 based on thermally coupled energy levels (TCELs) 2 H 11/2 and 4 S 3/2 was studied via the fluorescence intensity ratio (FIR) technique. Thermometric parameters based on the ratio of Er 3+ transitions ( 2 H 11/2 → 4 I 15/2 and 4 S 3/2 → 4 I 15/2 ) results in ln I 520 /I 540 = 3.88−1086.83/T and ΔE∼ 755.34 cm −1 . Results revealed ΔT = 0.4 K at 297 K, and maximum relative sensitivity (S r ) and absolute sensitivity (S a ) values are 1.23% K −1 (at 297K) and 0.173% K −1 (at 397K), respectively. The energy transfer and thermal quenching process were demonstrated mechanistically. The Commission Internationale de l'E ́clairage (CIE) chromaticity diagram confirms the suitability of this material as a green light emitter. The unprecedented photostability and photoswitching behavior has been addressed by a photoelectrochemical cell experiment under light and dark conditions. Results suggest that Yb 3+ ,Er 3+ -activated NaBiF 4 is the most promising high-quality luminescent nanophosphor, reflecting the realm of scientific evolution and providing applications in luminescent thermometers, plasmon-enhanced UC luminescence, solid-state lighting, and fast switching photodetectors.
Engineering a single phosphor for multiple objectives is challenging and essential for innovative technology, enriching productivity and flexibility, lowering cost, minimizing power intake, etc. In this study, a Yb 3+ ,Er 3+ -activated NaBiF 4 nanophosphor synthesized via a thermolysis approach provided significant opportunity to explore the potential of single phosphor in diverse fields including contactless thermometry, plasmonenhanced upconversion luminescence (UCL), solid-state lighting, and photoswitching probes. The phosphor has been characterized using several standard techniques to unveil the phase, crystal structure, associated functional groups, morphology, crystalline nature, and optical properties. A 5-fold enhancement in UCL intensity was observed from Yb 3+ ,Er 3+ :NaBiF 4 @SiO 2 @Ag. Upconversion luminescence thermometry of Yb 3+ ,Er 3+ :NaBiF 4 based on thermally coupled energy levels (TCELs) 2 H 11/2 and 4 S 3/2 was studied via the fluorescence intensity ratio (FIR) technique. Thermometric parameters based on the ratio of Er 3+ transitions ( 2 H 11/2 → 4 I 15/2 and 4 S 3/2 → 4 I 15/2 ) results in ln I 520 /I 540 = 3.88−1086.83/T and ΔE∼ 755.34 cm −1 . Results revealed ΔT = 0.4 K at 297 K, and maximum relative sensitivity (S r ) and absolute sensitivity (S a ) values are 1.23% K −1 (at 297K) and 0.173% K −1 (at 397K), respectively. The energy transfer and thermal quenching process were demonstrated mechanistically. The Commission Internationale de l'E ́clairage (CIE) chromaticity diagram confirms the suitability of this material as a green light emitter. The unprecedented photostability and photoswitching behavior has been addressed by a photoelectrochemical cell experiment under light and dark conditions. Results suggest that Yb 3+ ,Er 3+ -activated NaBiF 4 is the most promising high-quality luminescent nanophosphor, reflecting the realm of scientific evolution and providing applications in luminescent thermometers, plasmon-enhanced UC luminescence, solid-state lighting, and fast switching photodetectors.
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