Zou, Wei

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  • Zou, Wei (1)
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Author's Bibliography

Unraveling Broadband Near-Infrared Luminescence in Cr3+-Doped Ca3Y2Ge3O12 Garnets: Insights from First-Principles Analysis

Zou, Wei; Lou, Bibo; Kurboniyon, Mekhrdod S.; Buryi, Maksym; Rahimi, Farhod; Srivastava, Alok M.; Brik, Mikhail G.; Wang, Jing; Ma, Chonggeng

(2024) 

TY  - JOUR
AU  - Zou, Wei
AU  - Lou, Bibo
AU  - Kurboniyon, Mekhrdod S.
AU  - Buryi, Maksym
AU  - Rahimi, Farhod
AU  - Srivastava, Alok M.
AU  - Brik, Mikhail G.
AU  - Wang, Jing
AU  - Ma, Chonggeng
PY  - 2024
UR  - https://vinar.vin.bg.ac.rs/handle/123456789/13187
AB  - In this study, we conducted an extensive investigation into broadband near-infrared luminescence of Cr3+-doped Ca3Y2Ge3O12 garnet, employing first-principles calculations within the density functional theory framework. Our initial focus involved determining the site occupancy of Cr3+ activator ions, which revealed a pronounced preference for the Y3+ sites over the Ca2+ and Ge4+ sites, as evidenced by the formation energy calculations. Subsequently, the geometric structures of the excited states 2E and 4T2, along with their optical transition energies relative to the ground state 4A2 in Ca3Y2Ge3O12:Cr3+, were successfully modeled using the ΔSCF method. Calculation convergence challenges were effectively addressed through the proposed fractional particle occupancy schemes. The constructed host-referred binding energy diagram provided a clear description of the luminescence kinetics process in the garnet, which explained the high quantum efficiency of emission. Furthermore, the accurate prediction of thermal excitation energy yielded insights into the thermal stability of the compound, as illustrated in the calculated configuration coordinate diagram. More importantly, all calculated data were consistently aligned with the experimental results. This research not only advances our understanding of the intricate interplay between geometric and electronic structures, optical properties, and thermal behavior in Cr3+-doped garnets but also lays the groundwork for future breakthroughs in the high-throughput design and optimization of luminescent performance and thermal stability in Cr3+-doped phosphors.
T2  - Materials
T1  - Unraveling Broadband Near-Infrared Luminescence in Cr3+-Doped Ca3Y2Ge3O12 Garnets: Insights from First-Principles Analysis
VL  - 17
IS  - 7
SP  - 1709
DO  - 10.3390/ma17071709
ER  - 
@article{
author = "Zou, Wei and Lou, Bibo and Kurboniyon, Mekhrdod S. and Buryi, Maksym and Rahimi, Farhod and Srivastava, Alok M. and Brik, Mikhail G. and Wang, Jing and Ma, Chonggeng",
year = "2024",
abstract = "In this study, we conducted an extensive investigation into broadband near-infrared luminescence of Cr3+-doped Ca3Y2Ge3O12 garnet, employing first-principles calculations within the density functional theory framework. Our initial focus involved determining the site occupancy of Cr3+ activator ions, which revealed a pronounced preference for the Y3+ sites over the Ca2+ and Ge4+ sites, as evidenced by the formation energy calculations. Subsequently, the geometric structures of the excited states 2E and 4T2, along with their optical transition energies relative to the ground state 4A2 in Ca3Y2Ge3O12:Cr3+, were successfully modeled using the ΔSCF method. Calculation convergence challenges were effectively addressed through the proposed fractional particle occupancy schemes. The constructed host-referred binding energy diagram provided a clear description of the luminescence kinetics process in the garnet, which explained the high quantum efficiency of emission. Furthermore, the accurate prediction of thermal excitation energy yielded insights into the thermal stability of the compound, as illustrated in the calculated configuration coordinate diagram. More importantly, all calculated data were consistently aligned with the experimental results. This research not only advances our understanding of the intricate interplay between geometric and electronic structures, optical properties, and thermal behavior in Cr3+-doped garnets but also lays the groundwork for future breakthroughs in the high-throughput design and optimization of luminescent performance and thermal stability in Cr3+-doped phosphors.",
journal = "Materials",
title = "Unraveling Broadband Near-Infrared Luminescence in Cr3+-Doped Ca3Y2Ge3O12 Garnets: Insights from First-Principles Analysis",
volume = "17",
number = "7",
pages = "1709",
doi = "10.3390/ma17071709"
}
Zou, W., Lou, B., Kurboniyon, M. S., Buryi, M., Rahimi, F., Srivastava, A. M., Brik, M. G., Wang, J.,& Ma, C.. (2024). Unraveling Broadband Near-Infrared Luminescence in Cr3+-Doped Ca3Y2Ge3O12 Garnets: Insights from First-Principles Analysis. in Materials, 17(7), 1709.
https://doi.org/10.3390/ma17071709
Zou W, Lou B, Kurboniyon MS, Buryi M, Rahimi F, Srivastava AM, Brik MG, Wang J, Ma C. Unraveling Broadband Near-Infrared Luminescence in Cr3+-Doped Ca3Y2Ge3O12 Garnets: Insights from First-Principles Analysis. in Materials. 2024;17(7):1709.
doi:10.3390/ma17071709 .
Zou, Wei, Lou, Bibo, Kurboniyon, Mekhrdod S., Buryi, Maksym, Rahimi, Farhod, Srivastava, Alok M., Brik, Mikhail G., Wang, Jing, Ma, Chonggeng, "Unraveling Broadband Near-Infrared Luminescence in Cr3+-Doped Ca3Y2Ge3O12 Garnets: Insights from First-Principles Analysis" in Materials, 17, no. 7 (2024):1709,
https://doi.org/10.3390/ma17071709 . .