The method of measuring temperature using luminescence by analyzing the emission spectra of Pr3+-doped YF3 using principal component analysis is presented. The Pr3+-doped YF3 is synthesized using a solid-state technique, and its single-phase orthorhombic crystal structure is confirmed using X-ray diffraction. The emission spectra measured within the 93–473 K temperature range displays characteristic Pr3+ f-f electronic transitions. The red emission from the 3P0,1→3H6,3F2 electronic transition mostly dominates the spectra. However, at low temperatures, the intensity of the green emissions from the 3P0,1→3H5, deep-red 3P0,1→3F4, and the deep-red emissions from the 3P0,1→3F4 transitions are considerably lower compared to the intensity of the red emissions. Temperature variations directly impact the photoluminescent spectra, causing a notable increase in the green and deep-red emissions from the 3P1 excited state. We utilized the entire spectrum as an input for principal component analysis..., considering each temperature as an independent group of data. The first principal component explained 99.3% of the variance in emission spectra caused by temperature and we further used it as a reliable temperature indicator for luminescence thermometry. The approach has a maximum absolute sensitivity of around 0.012 K−1. The average accuracy and precision values are 0.7 K and 0.5 K, respectively.
TY - JOUR
AU - Rajčić, Anđela
AU - Ristić, Zoran
AU - Periša, Jovana
AU - Milićević, Bojana
AU - Aldawood, Saad
AU - Alodhayb, Abdullah N.
AU - Antić, Željka
AU - Dramićanin, Miroslav
PY - 2024
UR - https://vinar.vin.bg.ac.rs/handle/123456789/13709
AB - The method of measuring temperature using luminescence by analyzing the emission spectra of Pr3+-doped YF3 using principal component analysis is presented. The Pr3+-doped YF3 is synthesized using a solid-state technique, and its single-phase orthorhombic crystal structure is confirmed using X-ray diffraction. The emission spectra measured within the 93–473 K temperature range displays characteristic Pr3+ f-f electronic transitions. The red emission from the 3P0,1→3H6,3F2 electronic transition mostly dominates the spectra. However, at low temperatures, the intensity of the green emissions from the 3P0,1→3H5, deep-red 3P0,1→3F4, and the deep-red emissions from the 3P0,1→3F4 transitions are considerably lower compared to the intensity of the red emissions. Temperature variations directly impact the photoluminescent spectra, causing a notable increase in the green and deep-red emissions from the 3P1 excited state. We utilized the entire spectrum as an input for principal component analysis, considering each temperature as an independent group of data. The first principal component explained 99.3% of the variance in emission spectra caused by temperature and we further used it as a reliable temperature indicator for luminescence thermometry. The approach has a maximum absolute sensitivity of around 0.012 K−1. The average accuracy and precision values are 0.7 K and 0.5 K, respectively.
T2 - Technologies
T1 - Using Principal Component Analysis for Temperature Readings from YF3:Pr3+ Luminescence
VL - 12
IS - 8
SP - 131
DO - 10.3390/technologies12080131
ER -
@article{
author = "Rajčić, Anđela and Ristić, Zoran and Periša, Jovana and Milićević, Bojana and Aldawood, Saad and Alodhayb, Abdullah N. and Antić, Željka and Dramićanin, Miroslav",
year = "2024",
abstract = "The method of measuring temperature using luminescence by analyzing the emission spectra of Pr3+-doped YF3 using principal component analysis is presented. The Pr3+-doped YF3 is synthesized using a solid-state technique, and its single-phase orthorhombic crystal structure is confirmed using X-ray diffraction. The emission spectra measured within the 93–473 K temperature range displays characteristic Pr3+ f-f electronic transitions. The red emission from the 3P0,1→3H6,3F2 electronic transition mostly dominates the spectra. However, at low temperatures, the intensity of the green emissions from the 3P0,1→3H5, deep-red 3P0,1→3F4, and the deep-red emissions from the 3P0,1→3F4 transitions are considerably lower compared to the intensity of the red emissions. Temperature variations directly impact the photoluminescent spectra, causing a notable increase in the green and deep-red emissions from the 3P1 excited state. We utilized the entire spectrum as an input for principal component analysis, considering each temperature as an independent group of data. The first principal component explained 99.3% of the variance in emission spectra caused by temperature and we further used it as a reliable temperature indicator for luminescence thermometry. The approach has a maximum absolute sensitivity of around 0.012 K−1. The average accuracy and precision values are 0.7 K and 0.5 K, respectively.",
journal = "Technologies",
title = "Using Principal Component Analysis for Temperature Readings from YF3:Pr3+ Luminescence",
volume = "12",
number = "8",
pages = "131",
doi = "10.3390/technologies12080131"
}
Rajčić, A., Ristić, Z., Periša, J., Milićević, B., Aldawood, S., Alodhayb, A. N., Antić, Ž.,& Dramićanin, M.. (2024). Using Principal Component Analysis for Temperature Readings from YF3:Pr3+ Luminescence. in Technologies, 12(8), 131.
https://doi.org/10.3390/technologies12080131
Rajčić A, Ristić Z, Periša J, Milićević B, Aldawood S, Alodhayb AN, Antić Ž, Dramićanin M. Using Principal Component Analysis for Temperature Readings from YF3:Pr3+ Luminescence. in Technologies. 2024;12(8):131.
doi:10.3390/technologies12080131 .
Rajčić, Anđela, Ristić, Zoran, Periša, Jovana, Milićević, Bojana, Aldawood, Saad, Alodhayb, Abdullah N., Antić, Željka, Dramićanin, Miroslav, "Using Principal Component Analysis for Temperature Readings from YF3:Pr3+ Luminescence" in Technologies, 12, no. 8 (2024):131,
https://doi.org/10.3390/technologies12080131 . .
