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Acta Optica Sinica, Volume. 40, Issue 24, 2430002(2020)

Development of Confocal LIBS Microscope On the Cover

Weihua Huang, Chunjing He, Weiqian Zhao**, and Lirong Qiu*
Author Affiliations
  • Beijing Key Laboratory for Precision Optoelectronic Measurement Instrument and Technology, School of Optics and Photonics, Beijing Institute of Technology, Beijing 100081, China
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    AbstractGet PDF(in Chinese)
    Figures&Tables (14)
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    References (24)
    Cited By (3)
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    Figures & Tables(14)
    Principle of confocal LIBS imaging system

    Fig. 1. Principle of confocal LIBS imaging system

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    Axial response curve for confocal LIBS imaging system

    Fig. 2. Axial response curve for confocal LIBS imaging system

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    Influence of pinhole size on the spatial resolution of confocal microscope. (a) Influence of pinhole size on FWHM and signal intensity of confocal lateral response curve; (b) influence of pinhole size on FWHM and signal intensity of confocal axial response curve

    Fig. 3. Influence of pinhole size on the spatial resolution of confocal microscope. (a) Influence of pinhole size on FWHM and signal intensity of confocal lateral response curve; (b) influence of pinhole size on FWHM and signal intensity of confocal axial response curve

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    LIBS spectrum collection module. (a) Collection light path of LIBS signals; (b) entrance of the collection fiber

    Fig. 4. LIBS spectrum collection module. (a) Collection light path of LIBS signals; (b) entrance of the collection fiber

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    Confocal LIBS imaging system

    Fig. 5. Confocal LIBS imaging system

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    Spatial resolution experimental results. (a) Axial focusing ability; (b) spatial resolution

    Fig. 6. Spatial resolution experimental results. (a) Axial focusing ability; (b) spatial resolution

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    Relationship between spatial resolution and LIBS intensity. (a) Ablation craters under different energy pulse lasers; (b) ablation craters' diameter, depth, volume and LIBS intensity under different energy pulse lasers; (c) ablation craters by pulse laser at different defocus distances; (d) ablation craters' diameter, depth, volume and LIBS intensity by pulsed laser at different defocus distances

    Fig. 7. Relationship between spatial resolution and LIBS intensity. (a) Ablation craters under different energy pulse lasers; (b) ablation craters' diameter, depth, volume and LIBS intensity under different energy pulse lasers; (c) ablation craters by pulse laser at different defocus distances; (d) ablation craters' diameter, depth, volume and LIBS intensity by pulsed laser at different defocus distances

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    Agate ore sample. (a) White light image of the tested sample; (b) LIBS spectrum of the tested sample (480-600 nm)

    Fig. 8. Agate ore sample. (a) White light image of the tested sample; (b) LIBS spectrum of the tested sample (480-600 nm)

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    3D fusion maps. (a)CCD image; (b)-(f) 3D maps of Ba, Ti, Ca, Cu, Fe

    Fig. 9. 3D fusion maps. (a)CCD image; (b)-(f) 3D maps of Ba, Ti, Ca, Cu, Fe

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    Results of pulsed energy

    Fig. 10. Results of pulsed energy

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    Results of laser focusing

    Fig. 11. Results of laser focusing

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    Results of pulsed energy

    Fig. 12. Results of pulsed energy

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    • Table 1. Parameters of three different types of plano-convex quartz lensesunit: mm

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      Table 1. Parameters of three different types of plano-convex quartz lensesunit: mm

      TypeDiameterfocal lengthRadius of curvatureCenter thicknessEdge thickness
      LA472525.475.334.54.42
      LA438025.4100.346.03.82
      LA423625.4125.457.53.42

    • Table 2. RMS radius of the focus spot for three different types of plano-convex lensesunit: μm

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      Table 2. RMS radius of the focus spot for three different types of plano-convex lensesunit: μm

      TypeRadiusAverage radius
      A or CB
      LA4725617.8384.8501.3
      LA4380731.4650.3690.8
      LA4236901.4921.4911.4
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    Weihua Huang, Chunjing He, Weiqian Zhao, Lirong Qiu. Development of Confocal LIBS Microscope[J]. Acta Optica Sinica, 2020, 40(24): 2430002

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    Paper Information

    Category: Spectroscopy

    Received: Aug. 20, 2020

    Accepted: Sep. 25, 2020

    Published Online: Dec. 3, 2020

    The Author Email: Zhao Weiqian (zwq669@126.com), Qiu Lirong (qiugrass@126.com)

    DOI:10.3788/AOS202040.2430002

    Topics

    laser devices and laser physics
    Lasers and Laser Optics
    Laser physics
    laser manufacturing
    Instrumentation, Measurement and Metrology