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Chinese Journal of Lasers, Volume. 47, Issue 5, 0501001(2020)

Numerical Simulation of Solid-State Lasers Based on Secondary Raman Modes

Jie Xu, Xiaohua Che, Hengda Li, Shumei Wang, and Shuanghong Ding*
Author Affiliations
  • School of Photo-Electronic Information Science and Technology, Yantai University, Yantai, Shandong 264005, China
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    Figures & Tables(7)
    Pulse output characteristics versus K2/K1 when N takes different values. (a)Peak power ΦS1max of Raman light 1 and peak power ΦS2max of Raman light 2; (b) pulse energy ΦS1int of Raman light 1 and pulse energy ΦS2int of Raman light 2; (c) pulse width τS1 of Raman light 1 and pulse width τS2 of Raman light 2; (d) critical value of K2</su

    Fig. 1. Pulse output characteristics versus K2/K1 when N takes different values. (a)Peak power ΦS1max of Raman light 1 and peak power ΦS2max of Raman light 2; (b) pulse energy ΦS1int of Raman light 1 and pulse energy ΦS2int of Raman light 2; (c) pulse width τS1 of Raman light 1 and pulse width τS2 of Raman light 2; (d) critical value of K2

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    Pulse output characteristics versus K2/K1 when M2 takes different values.(a)Peak power ΦS1max of Raman light 1 and peak power ΦS2max of Raman light 2; (b) pulse energy ΦS1int of Raman light 1 and pulse energy ΦS2int of Raman light 2; (c) pulse width τS1 of Raman light 1 and pulse width τS2 of Raman light 2; (d) critical value of K</i

    Fig. 2. Pulse output characteristics versus K2/K1 when M2 takes different values.(a)Peak power ΦS1max of Raman light 1 and peak power ΦS2max of Raman light 2; (b) pulse energy ΦS1int of Raman light 1 and pulse energy ΦS2int of Raman light 2; (c) pulse width τS1 of Raman light 1 and pulse width τS2 of Raman light 2; (d) critical value of K

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    Pulse output characteristics versus K2/K1 when α takes different values. (a) Peak power ΦS1max of Raman light 1 and peak power ΦS2max of Raman light 2; (b) pulse energy ΦS1int of Raman light 1 and pulse energy ΦS2int of Raman light 2; (c) pulse width τS1 of Raman light 1 and pulse width τS2 of Raman light 2; (d) critical value of K2</s

    Fig. 3. Pulse output characteristics versus K2/K1 when α takes different values. (a) Peak power ΦS1max of Raman light 1 and peak power ΦS2max of Raman light 2; (b) pulse energy ΦS1int of Raman light 1 and pulse energy ΦS2int of Raman light 2; (c) pulse width τS1 of Raman light 1 and pulse width τS2 of Raman light 2; (d) critical value of K2

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    Pulse output characteristics versus α when N takes different values. (a) Peak power ΦS1max of Raman light 1 and peak power ΦS2max of Raman light 2; (b) pulse energy ΦS1int of Raman light 1 and pulse energy ΦS2int of Raman light 2; (c) pulse width τS1 of Raman light 1 and pulse width τS2 of Raman light 2

    Fig. 4. Pulse output characteristics versus α when N takes different values. (a) Peak power ΦS1max of Raman light 1 and peak power ΦS2max of Raman light 2; (b) pulse energy ΦS1int of Raman light 1 and pulse energy ΦS2int of Raman light 2; (c) pulse width τS1 of Raman light 1 and pulse width τS2 of Raman light 2

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    Pulse output characteristics versus M2/M1 when N takes different values. (a) Peak power ΦS1max of Raman light 1; (b) pulse energy ΦS1int of Raman light 1; (c) pulse width τS1 of Raman light 1

    Fig. 5. Pulse output characteristics versus M2/M1 when N takes different values. (a) Peak power ΦS1max of Raman light 1; (b) pulse energy ΦS1int of Raman light 1; (c) pulse width τS1 of Raman light 1

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    Experimental results of peak power ΦS1max of 1097 nm Raman light versus K2/K1

    Fig. 6. Experimental results of peak power ΦS1max of 1097 nm Raman light versus K2/K1

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    • Table 1. Range of normalized parameters

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      Table 1. Range of normalized parameters

      ParameterαKspNM2M2/ M1K1K2/ K1
      Value10--3010-11--10-122.5--5.510--251--5[15]0.2--0.310--50
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    Jie Xu, Xiaohua Che, Hengda Li, Shumei Wang, Shuanghong Ding. Numerical Simulation of Solid-State Lasers Based on Secondary Raman Modes[J]. Chinese Journal of Lasers, 2020, 47(5): 0501001

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    Paper Information

    Category: laser devices and laser physics

    Received: Oct. 14, 2019

    Accepted: Dec. 19, 2019

    Published Online: May. 12, 2020

    The Author Email: Ding Shuanghong (shding@ytu.edu.cn)

    DOI:10.3788/CJL202047.0501001

    Topics

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