Review of Kinetic Impact Deflection of Near-Earth Objects

被引:0
|
作者
Liu W. [1 ]
Zhang Q. [1 ]
Long R. [1 ]
Ren J. [1 ]
Gong Z. [2 ]
Ren S. [2 ]
Wu Q. [2 ]
Song G. [2 ]
Chen C. [2 ]
Zhang P. [2 ]
机构
[1] State Key Laboratory of Explosion Science and Technology, Beijing Institute of Technology, Beijing
[2] Beijing Institute of Spacecraft Environment Engineering, Beijing
来源
Yuhang Xuebao/Journal of Astronautics | 2023年 / 44卷 / 01期
关键词
Hypervelocity impact; Kinetic deflection; Near-Earth objects; Planetary defense; Scaling law;
D O I
10.3873/j.issn.1000-1328.2023.01.002
中图分类号
学科分类号
摘要
With the defense of near-Earth objects as the background, the basic concepts and physical characteristics of small near-Earth objects are introduced and the research progress on the kinetic deflection of near-Earth objects is reviewed. The cratering morphology, generation mechanism, mass velocity distribution, and scaling law of ejecta material by impact are discussed. Based on the point source hypothesis and experimental and numerical simulation results, the theoretical model and similarity law of momentum transfer are summarized. The influence of the physical characteristics of the near-Earth objects and impact conditions on the momentum transfer coefficient is analyzed. Finally, the problems in the study of kinetic deflection of near-Earth objects are summarized, and some suggestions on the future research trends of kinetic deflection of near-Earth objects are put forward. © 2023 China Spaceflight Society. All rights reserved.
引用
收藏
页码:9 / 24
页数:15
相关论文
共 120 条
  • [1] RUMPF C M, MATHIAS D L, WHEELER L F, Et al., Deflection driven evolution of asteroid impact risk under large uncertainties, Acta Astronautica, 176, pp. 276-286, (2020)
  • [2] OSINSKI C R, GRIEVE R, FERRIERE L, Et al., Impact Earth: A review of the terrestrial impact record, Earth Science Reviews, 232, (2022)
  • [3] CHIARENZA A A, FARNSWORTH A, MANNION P D, Et al., Asteroid impact, not volcanism, caused the end-Cretaceous dinosaur extinction [J], Proceedings of the National Academy of Sciences of the United States of America, 117, 29, pp. 17084-17093, (2020)
  • [4] GLADYSHEVA O., The Tunguska event, Icarus, 348, (2020)
  • [5] POPOVA O P, JENNISKENS P, EMEL'YANENKO V, Et al., Chelyabinsk airburst, damage assessment, meteorite recovery, and characterization, Science, 342, 6162, pp. 1069-1073, (2013)
  • [6] BROWN P C, ASSINK J D, ASTIZ L, Et al., A 500-kiloton airburst over Chelyabinsk and an enhanced hazard from small impactors, Nature, 503, 7475, pp. 238-241, (2013)
  • [7] KULACIN V P, SHUSTOV B M, KUZNETSOV Y M, Et al., Methods and means of information-analytical assessment of asteroid and comet hazard [J], Solar System Research, 50, 7, pp. 464-470, (2017)
  • [8] BOARD S S., Defending planet earth: Near-Earth-Object surveys and hazard mitigation strategies, (2010)
  • [9] PERNA D, BARUCCI M A, FULCHIGNONI M., The near-Earth objects and their potential threat to our planet [J], The Astronomy and Astrophysics Review, 21, 1, pp. 1-28, (2013)
  • [10] GONG Zizheng, LI Ming, CHEN Chuan, Et al., The frontier science and key technologies of asteroid monitoring and early warning, security defense and resource utilization, Chinese Science Bulletin, 65, 5, pp. 346-372, (2020)
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