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    Journals >Infrared and Laser Engineering >Volume 50 >Issue 3 >Page 20200253 > Article
    • Infrared and Laser Engineering
    • Vol. 50, Issue 3, 20200253 (2021)
    Numerical study of shock wave drag reduction mechanism by nanosecond-pulse laser energy deposition
    Diankai Wang, Jilin Shi, and Zexu Qing
    Author Affiliations
  • State Key Laboratory of Laser Propulsion & Application, Space Engineering University, Beijing 101416, China
    • show less
    DOI: 10.3788/IRLA20200253 Cite this Article
    Diankai Wang, Jilin Shi, Zexu Qing. Numerical study of shock wave drag reduction mechanism by nanosecond-pulse laser energy deposition[J]. Infrared and Laser Engineering, 2021, 50(3): 20200253 Copy Citation Text show less
    References

    [1] A C Olivera, M A Minucci, L N Mybrabo, et al. Bow shock wave mitigation by laser-plasma energy addition in hypersonic flow. Journal of Spacecraft and Rockets, 45, 921-927(2008).

    [2] P K Tret'yakov, A F Garanin, G N Grachev, et al. Control of supersonic flow around bodies by means of high-power recurrent optical breakdowns. Physics-Doklady, 41, 566-567(1996).

    [3] Sasoh A, Sekiya Y, Sakai T, et al. Drag reduction of blunt body in a supersonic flow with laser energy depositions[C]47th AIAA Aerospace Sciences Meeting Including The New Hizons Fum Aerospace Exposition. AIAA 20091533, 2009.

    [4] O A Azarova. Supersonic flow control using combined energy deposition. Aerospace, 2, 118-134(2015).

    [5] Markhotok A A. Mechanism of vtex generation in a supersonic flow behind a gasplasma interface[JOL]. [20191022]. http:arxiv.gabs1703.10727.

    [6] Ming Wen, Diankai Wang, Weidong Wang. Influence of key parameters on the interaction of the laser induced plasma hot core and shock wave. Infrared and Laser Engineering, 48, 0406001(2019).

    [7] Weidong Wang, Ming Wen, Diankai Wang, . Study on the flow characteristics of interaction of the laser induced plasma hot core and shock wave. Infrared and Laser Engineering, 48, 0306001(2019).

    [8] S Desai, V Kulkarni, H Gadgil, et al. Aerothermodynamic considerations for energy deposition based drag reduction technique. Applied Thermal Engineering, 122, 451-460(2017).

    [9] Ds I G. Laser spark ignition modeling[D]. Tennessee: University of Tennessee, 2000: 725.

    [10] Zexu Qing, Yanji Hong, Diankai Wang, . Experimental and numerical study of nanosecond pulsed laser energy asymetric deposition in quiescent air. Journal of Propulsion Technology, 38, 1661-1668(2017).

    [11] Y L Chen, J Lewis, C Parigger. Spatial and temporal profiles of pulsed laser-induced air plasma emissions. Journal of Quantitative Spectroscopy and Radiative Transfer, 67, 91-103(2000).

    [13] A Murphy. Transport coefficients of air, argon-air, nitrogen-air, and oxygen-air plasmas. Plasma Chemistry and Plasma Processing, 15, 279-307(1995).

    [15] A Sasoh, Y Sekiya, T Sakai, et al. Supersonic drag reduction with repetitive laser pulses through a blunt body. AIAA Journal, 48, 2811-2817(2010).

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    Diankai Wang, Jilin Shi, Zexu Qing. Numerical study of shock wave drag reduction mechanism by nanosecond-pulse laser energy deposition[J]. Infrared and Laser Engineering, 2021, 50(3): 20200253
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