Spectroscopy and Spectral Analysis, Volume. 42, Issue 1, 86(2022)
Development and Application of Fluorescence Suppression Based on Multi Wavelength Raman Spectrometer
Figures & Tables(9)
Fig. 1. Shift difference Raman schematic
(a): Two single-wavelength Raman original spectra; (b): Differential Raman raw spectra; (c): The reconstructed Raman spectrum
Fig. 2. The relationship between the wavelength of the laser and its excitation and scattering efficiency
Fig. 3. Schematic diagram of the instrument structure
1: Laser line filter; 2: Reflecting mirror; 3: Laser dichroic mirror; 4: Rayleigh filter; 5: Spectrometer coupling focusing mirror;6: Spectral dichroic mirror; 7: Objective lens
Fig. 5. Polystyrene Raman spectra under different detection methods
(a): Differential single wavelength 784.5 and 785.5 nm Raman detection results under synchronous test; (b): Differential single wavelength 784.5 and 785.5 nm Raman detection results under time-sharing sequential test; (c): Synchronous test near 1 064 nm Infrared Raman detection results; (d): 1 064 nm near-infrared Raman detection results under time-sharing successive test
Fig. 6. Acetone detection results based on multi-wavelength anti-fluorescence Raman spectrometer
(a1): Original acetone Raman spectrum; (b1): Acetone reconstructed Raman spectrum; (c1): Acetone 1 064 near-infrared Raman spectrum; (a2): Original acetonitrile Raman spectrum; (b2): Acetonitrile reconstructed Raman spectrum; (c2): Acetonitrile 1 064 near-infrared Raman spectrum
Fig. 7. The detection results of edible oil and red BBS plastic particles based on multi-wavelength de-fluorescence Raman spectrometer
(a1): Original edible oil Raman spectrum; (b1): Edible oil reconstructed Raman spectrum; (c1): Edible oil 1 064 near-infrared Raman spectrum;(a2): Original red BBS plastic particles Raman spectrum; (b2): Red BBS plastic particles reconstructed Raman spectrum;(c2): Red BBS plastic particles 1 064 near-infrared Raman spectrum
Fig. 8. Detection results of red wine and gray plastic particles based on multi-wavelength defluorescence Raman spectrometer
(a1): Original red wine Raman spectrum; (b1): Red wine reconstructed Raman spectrum; (c1): Red wine 1 064 near-infrared Raman spectrum; (a2): Original gray plastic particles Raman spectrum; (b2): Gray plastic particles reconstructed Raman spectrum; (c2): Gray plastic particles 1 064 near-infrared Raman spectrum
Table 1. Comparison of raw data of different detection methods
View tableView in ArticleTable 1. Comparison of raw data of different detection methods
检测方式 激光光源 强度 峰位 均值 稳定性
/%标准
偏差准确度 稳定性 同步测试 784.5 nm 49 735 0.11 16.9 ±0.03 0.040 785.5 nm 49 727 0.27 38.4 ±0.03 0.042 1 064 nm 24 501 0.51 41.1 ±0.02 0.044 分时逐次
测试784.5 nm 49 716 0.19 30.8 ±0.03 0.046 785.5 nm 49 720 0.28 43.2 ±0.02 0.038 1 064 nm 24 515 0.33 28.1 ±0.02 0.039
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Ying ZHAO, Xiao-peng LI, Fei-peng CUI, Jia LIU, Xiao-jia LI. Development and Application of Fluorescence Suppression Based on Multi Wavelength Raman Spectrometer[J]. Spectroscopy and Spectral Analysis, 2022, 42(1): 86
Paper Information
Category: Research Articles
Received: Nov. 17, 2020
Accepted: --
Published Online: Mar. 31, 2022
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