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High Power Laser and Particle Beams, Volume. 34, Issue 12, 126002(2022)

Dependence of tungsten melting and resolidification on pulse parameters under transient heat flow

Miao Qu1,2 and Sha Yan2、*
Author Affiliations
  • 1China Nuclear Strategic Planning Research Institute Co., Ltd., Beijing 100048, China
  • 2Institute of Heavy Ion Physics, Peking University, Beijing 100871, China
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    AbstractGet PDF(in Chinese)
    Figures&Tables (8)
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    References (25)
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    Figures & Tables(8)
    SEM images and diagram of tungsten under compressed plasma flow (CPF) single pulse irradiation with pulse width of 0.1 ms

    Fig. 1. SEM images and diagram of tungsten under compressed plasma flow (CPF) single pulse irradiation with pulse width of 0.1 ms

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    VCD diagram of tungsten cross section under CPF single pulse irradiation with pulse width of 0.1 ms

    Fig. 2. VCD diagram of tungsten cross section under CPF single pulse irradiation with pulse width of 0.1 ms

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    SEM images of solidified droplet and stripping structure on tungsten under CPF single pulse irradiation with energy density of 1.54 MJ/m2 and pulse width of 0.1 ms

    Fig. 3. SEM images of solidified droplet and stripping structure on tungsten under CPF single pulse irradiation with energy density of 1.54 MJ/m2 and pulse width of 0.1 ms

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    SEM images and diagram of tungsten irradiated by 30 IPEB pulses with energy density of 3.82 MJ/m2 and pulse width of 5 ms

    Fig. 4. SEM images and diagram of tungsten irradiated by 30 IPEB pulses with energy density of 3.82 MJ/m2 and pulse width of 5 ms

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    The cross-sectional temperature distribution of tungsten at 5 ms after IPEB single pulse irradiation with energy density of 3.82 MJ/m2 and pulse width of 5 ms

    Fig. 5. The cross-sectional temperature distribution of tungsten at 5 ms after IPEB single pulse irradiation with energy density of 3.82 MJ/m2 and pulse width of 5 ms

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    The evolution of surface temperature with time at the center of irradiation area under 1-10 pulses of IPEB at 3.82 MJ/m2 energy density and 5 ms pulse width

    Fig. 6. The evolution of surface temperature with time at the center of irradiation area under 1-10 pulses of IPEB at 3.82 MJ/m2 energy density and 5 ms pulse width

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    Distribution of temperature at the center of irradiation area with depth under 1-10 pulses of IPEB at 3.82 MJ/m2 energy density and 5 ms pulse width

    Fig. 7. Distribution of temperature at the center of irradiation area with depth under 1-10 pulses of IPEB at 3.82 MJ/m2 energy density and 5 ms pulse width

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    • Table 1. The calculated thermal characteristics of tungsten irradiated by two kinds of pulse beams with pulse width of 5 ms and 0.1 ms

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      Table 1. The calculated thermal characteristics of tungsten irradiated by two kinds of pulse beams with pulse width of 5 ms and 0.1 ms

      particle type energy density/ (MJ·m−2) pulse width/ms melting time/ms melting layer thickness/μm
      IPEB3.8251.360
      CPF1.20.10.09332
      particle type temperature rise rate/(K·s−1) temperature drop rate/(K·s−1) maximum axial temperature gradient/(K·m−1) maximum radial temperature gradient/(K·m−1)
      IPEB5×1063×1064×1065×106
      CPF3×1086×1072×108
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    Miao Qu, Sha Yan. Dependence of tungsten melting and resolidification on pulse parameters under transient heat flow[J]. High Power Laser and Particle Beams, 2022, 34(12): 126002

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    Paper Information

    Category: Nuclear Science and Engineering

    Received: Jun. 8, 2022

    Accepted: Oct. 19, 2022

    Published Online: Nov. 10, 2022

    The Author Email: Yan Sha (syan@pku.edu.cn)

    DOI:10.11884/HPLPB202234.220192

    Topics

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