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    Journals >Spectroscopy and Spectral Analysis >Volume 42 >Issue 11 >Page 3512 > Article
    • Spectroscopy and Spectral Analysis
    • Vol. 42, Issue 11, 3512 (2022)
    Peak Splitting Method of Ion-Beam-Induced-Luminescence Spectrum Based on Voigt Function Fitting
    Guo-qiang ZHAO*, Meng-lin QIU1; *;, Jin-fu ZHANG1;, Ting-shun WANG1;, and Guang-fu WANG1; 2; *;
    Author Affiliations
  • 1. Key Laboratory of Beam Technology of Ministry of Education, College of Nuclear Science and Technology, Beijing Normal University, Beijing 100875, China
    • show less
    DOI: 10.3964/j.issn.1000-0593(2022)11-3512-07 Cite this Article
    Guo-qiang ZHAO, Meng-lin QIU, Jin-fu ZHANG, Ting-shun WANG, Guang-fu WANG. Peak Splitting Method of Ion-Beam-Induced-Luminescence Spectrum Based on Voigt Function Fitting[J]. Spectroscopy and Spectral Analysis, 2022, 42(11): 3512 Copy Citation Text show less
    Normalized IBIL energy spectrum at different fluences at 100 and 200 K
    Fig. 1. Normalized IBIL energy spectrum at different fluences at 100 and 200 K
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    Schematic diagram of Gauss and Voigt functions for IBIL energy spectrum of (a) 100 K and (b) 200 K with fluence of 6.22×1011 ions·cm-2 peak splittingThe green and the red line are the results obtained by using Gauss and Voigt functions to separate peaks, respectively
    Fig. 2. Schematic diagram of Gauss and Voigt functions for IBIL energy spectrum of (a) 100 K and (b) 200 K with fluence of 6.22×1011 ions·cm-2 peak splitting
    The green and the red line are the results obtained by using Gauss and Voigt functions to separate peaks, respectively
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    The peak position using Gauss and Voigt functions to split the IBIL spectra at (a) 100 K and (b) 200 K evolves with fluence
    Fig. 3. The peak position using Gauss and Voigt functions to split the IBIL spectra at (a) 100 K and (b) 200 K evolves with fluence
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    The Lorentz peak FWHM (wL) and Gaussian peak FWHM (wG) of three sub-peaks obtained by the Voigt function splitting the IBIL energy spectrum evolve with fluenceThe FWHM of the Gaussian peak evolves with the fluence at (a) 100 K and (b) 200 K; The FWHM of Lorentz Peak evolves with the fluence at (c) 100 K and (d) 200 K
    Fig. 4. The Lorentz peak FWHM (wL) and Gaussian peak FWHM (wG) of three sub-peaks obtained by the Voigt function splitting the IBIL energy spectrum evolve with fluence
    The FWHM of the Gaussian peak evolves with the fluence at (a) 100 K and (b) 200 K; The FWHM of Lorentz Peak evolves with the fluence at (c) 100 K and (d) 200 K
    Download full size | View in the Article
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    Guo-qiang ZHAO, Meng-lin QIU, Jin-fu ZHANG, Ting-shun WANG, Guang-fu WANG. Peak Splitting Method of Ion-Beam-Induced-Luminescence Spectrum Based on Voigt Function Fitting[J]. Spectroscopy and Spectral Analysis, 2022, 42(11): 3512
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