Title :
Er3+ Upconversion Fluorescence of ErNbO4 Phosphor for Optical Temperature Sensing
Author :
De-Long Zhang ; Zhi-Pei Hou ; Fang Han ; Ping-Rang Hua ; Dao-Yin Yu ; Pun, Edwin Yue-Bun
Author_Institution :
Sch. of Precision Instrum. & Opto-Electron. Eng., Tianjin Univ., Tianjin, China
Abstract :
Er3+ upconversion (UC) fluorescent characteristics of ErNbO4 phosphor were studied for temperature sensing purposes. This letter shows that the ErNbO4 phosphor emits more UC fluorescence than the Er3+-doped LiNbO3 single-crystal and Er3NbO7 phosphor. Both energy-transfer UC and excited state absorption play a role in the UC emission. Both the peak and integrated UC intensities decrease with the raised temperature, and the 530, 560, and 670 nm UC intensities reduce by (sim 26) %, 42%, and 34%, respectively, with the temperature rise of only 57 °C from 21 °C, implying that the phosphor is applicable to temperature sensing based upon either the 560- or 670-nm emission. The feasibility to realize the temperature sensing is discussed from the application requirements of smartness and low-cost, suggesting that not only the single 560- or 670-nm band, but the combined 530- and 560-nm bands can be also utilized.
Keywords :
erbium; fluorescence; light absorption; lithium compounds; niobium compounds; optical sensors; phosphors; temperature sensors; ErNbO4; LiNbO3:Er3+; energy-transfer UC; erbium ion upconversion fluorescence characteristics; erbium ion-doped lithium niobate single-crystal; excited state absorption; integrated UC intensities; optical temperature sensing; phosphor; temperature 21 degC; temperature 57 degC; wavelength 530 nm; wavelength 560 nm; wavelength 670 nm; Fluorescence; Green products; Lithium niobate; Phosphors; Powders; Temperature sensors; ErNbO4 phosphor; thermal effect; upconversion;
Journal_Title :
Photonics Technology Letters, IEEE
DOI :
10.1109/LPT.2014.2328094
