Kinetic Parameters analysis of GdAlO\(_3\) based on thermoluminescent phenomenon

{We herein report on the calculation of thermoluminescence (TL) kinetic parameters determined from the TL emission of synthetic GdAlO3 (GAO) phosphors prepared by the co-precipitation method. The sample, characterized by means of X-ray diffraction with an orthorhombic phase structure (space group Pn...

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Bibliographic Details
Published in:arXiv.org 2024-06
Main Authors: Nolasco-Altamirano, D, Romero-Nuñez, C S, Alonso-Sotolongoza, A, Benavente, J F, García-Salcedo, R, García-Garduño, O A, Zarate-Medina, J, Correcher, V, T Rivera Montalvo
Format: Article
Language:English
Subjects:
Glow curves
Heating rate
Orthorhombic phase
Parameters
Phosphors
Solid phases
Thermoluminescence
Online Access:Get full text
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Summary:{We herein report on the calculation of thermoluminescence (TL) kinetic parameters determined from the TL emission of synthetic GdAlO3 (GAO) phosphors prepared by the co-precipitation method. The sample, characterized by means of X-ray diffraction with an orthorhombic phase structure (space group Pnma (62), shows complex glow curves consisting of at least four groups of components peaked at 100, 140, 240, and 290 {\deg}C where the two lower overlapped temperature peaks are difficult to identify using the \(T_M-T_{stop}\). The coexistence of a continuum in the trap distribution (linked to the lower temperature peaks) and a discrete trap system (associated with the components at temperatures higher than 200 {\deg}C) can be distinguished. The estimation of the TL kinetic parameters is performed using GlowFit, TLAnal, the spreadsheet Origin, Computing Glow Curve Deconvolution (CGCD), and various heating rate (VHR) methods. However, only CGCD appears as the suitable technique for such purpose since it provides information on the TL physical process supported by mathematical models based on a linear combination of functions related to the First Order Kinetic approach.
ISSN:2331-8422
DOI:10.48550/arxiv.2406.01312