TY - JOUR
T1 - Excited state luminescence signals from a random distribution of defects
T2 - A new Monte Carlo simulation approach for feldspar
AU - Pagonis, Vasilis
AU - Friedrich, Johannes
AU - Discher, Michael
AU - Müller-Kirschbaum, Anna
AU - Schlosser, Veronika
AU - Kreutzer, Sebastian
AU - Chen, Reuven
AU - Schmidt, Christoph
N1 - Funding Information:
The work by MD, AMK, VS and CS are supported by the project ‘ULTIMO: Unifying Luminescence Models of quartz and feldspar’ (German Academic Exchange Service) DAAD: Deutscher Akademischer Austauschdienst DAAD PPP USA 2018, ID: 57387041 ).
Funding Information:
The work of SK is financed by a program supported by the ANR – no ANR-10-LABX-52 (France).
Publisher Copyright:
© 2018 Elsevier B.V.
PY - 2019/3/1
Y1 - 2019/3/1
N2 - This paper presents Monte Carlo simulations of tunneling recombination in random distributions of defects. Simulations are carried out for four common luminescence phenomena in solids exhibiting tunneling recombination, namely continuous wave infrared stimulated luminescence (CW-IRSL), thermoluminescence (TL), isothermal thermoluminescence (iso-TL) and linearly modulated infrared stimulated luminescence (LM-IRSL). Previous modeling work has shown that these phenomena can be described by the same partial differential equation, which must be integrated numerically over two variables, the elapsed time and the donor-acceptor distance. We here present a simple and fast Monte Carlo approach which can be applied to these four phenomena, and which reproduces the solution of the partial differential equation, without the need for numerical integrations. We show that the method is also applicable to cases of truncated distributions of nearest neighbor distances, which characterize samples that underwent multiple optical or thermal pretreatments. The accuracy and precision of the Monte Carlo method are tested by comparing with experimental data from several feldspar samples.
AB - This paper presents Monte Carlo simulations of tunneling recombination in random distributions of defects. Simulations are carried out for four common luminescence phenomena in solids exhibiting tunneling recombination, namely continuous wave infrared stimulated luminescence (CW-IRSL), thermoluminescence (TL), isothermal thermoluminescence (iso-TL) and linearly modulated infrared stimulated luminescence (LM-IRSL). Previous modeling work has shown that these phenomena can be described by the same partial differential equation, which must be integrated numerically over two variables, the elapsed time and the donor-acceptor distance. We here present a simple and fast Monte Carlo approach which can be applied to these four phenomena, and which reproduces the solution of the partial differential equation, without the need for numerical integrations. We show that the method is also applicable to cases of truncated distributions of nearest neighbor distances, which characterize samples that underwent multiple optical or thermal pretreatments. The accuracy and precision of the Monte Carlo method are tested by comparing with experimental data from several feldspar samples.
KW - Excited state luminescence in feldspars
KW - Feldspar model
KW - Monte Carlo model
UR - http://www.scopus.com/inward/record.url?scp=85057026745&partnerID=8YFLogxK
U2 - 10.1016/j.jlumin.2018.11.024
DO - 10.1016/j.jlumin.2018.11.024
M3 - Article
SN - 0022-2313
VL - 207
SP - 266
EP - 272
JO - Journal of Luminescence
JF - Journal of Luminescence
ER -