Exploiting novel optical thermometry near room temperature with a combination of phase-change host and luminescent Pr3+ ion

•The reversible phase transition between β- and α-LiYO2 is close to room temperature.•the phase transformation process modifies the local site symmetry of the Pr3+ sites.•The photoluminescence behaviors of Pr3+ in the two LiYO2 phases are distinct.•The largest relative sensitivity of Pr3+:LiYO2 can...

Full description

Saved in:
Bibliographic Details
Published in:Chemical engineering journal (Lausanne, Switzerland : 1996) Switzerland : 1996), 2021-06, Vol.414, p.128884, Article 128884
Main Authors: Wang, Shuxian, Zhang, Jinpu, Ye, Zhengmao, Yu, Haohai, Zhang, Huaijin
Format: Article
Language:English
Subjects:
Color adjustment
Optical thermometry
Phase transition
Photoluminescence
Pr3+ ions
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:•The reversible phase transition between β- and α-LiYO2 is close to room temperature.•the phase transformation process modifies the local site symmetry of the Pr3+ sites.•The photoluminescence behaviors of Pr3+ in the two LiYO2 phases are distinct.•The largest relative sensitivity of Pr3+:LiYO2 can reach 23.04%·K−1 (at 329 K).•Pr3+:LiYO2 also shows promising thermochromic and anti-counterfeiting applications. Luminescence thermometry manifests tremendous application potential in the optoelectronic field, and highly sensitive response to an alteration in temperature is their important development direction. Herein, we propose a Pr3+-doped LiYO2 phosphor that shows outstanding temperature sensing performance approaching room temperature (320–330 K). The thermal and structural investigations reveal that the phase transition of LiYO2 between the low-temperature (β) and high-temperature (α) phases is reversible. Along with the phase transformation from the β-type to the α-type, the local site symmetry of the Pr3+-doped sites is modified, leading to a dramatic reduction of the 3P0 emission in comparison to the 1D2 one. Such an obvious photoluminescence change through the phase transformation process presents outstanding optical thermometric performance, yielding a relative sensitivity Sr of 23.04%·K−1 at 329 K and a repeatability capability not lower than 98.9%. Moreover, By virtue of the excellent color variation of fluorescence in a temperature interval of ~30 K, the as-prepared samples also demonstrate promising thermochromic and anti-counterfeiting applications. Hence, our findings might offer some useful inspiration for exploring high-performance luminescent thermometers and understanding the structure-property relationship in material science.
ISSN:1385-8947
1873-3212
DOI:10.1016/j.cej.2021.128884