In order to improve our understanding of landing on small bodies and of asteroid evolution, we use our novel drop tower facility citep{sunday2016} to perform low-velocity (2 - 40 cm/s), shallow impact experiments of a 10 cm diameter aluminum sphere into quartz sand in low effective gravities (~0.2 - 1 m/s^2). Using in-situ accelerometers we measure the acceleration profile during the impacts and determine the peak accelerations, collision durations and maximum penetration depth. We find that the penetration depth scales linearly with the collision velocity but is independent of the effective gravity for the experimental range tested, and that the collision duration is independent of both the effective gravity and the collision velocity. No rebounds are observed in any of the experiments. Our low-gravity experimental results indicate that the transition from the quasi-static regime to the inertial regime occurs for impact energies two orders of magnitude smaller than in similar impact experiments under terrestrial gravity. The lower energy regime change may be due to the increased hydrodynamic drag of the surface material in our experiments, but may also support the notion that the quasi-static regime reduces as the effective gravity becomes lower.
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机译:为了增进对小物体着陆和小行星进化的了解,我们使用新颖的落塔装置 citep {sunday2016}进行直径为10 cm的低速(2-40 cm / s)浅冲击试验铝球以低有效重力(〜0.2-1 m / s ^ 2)进入石英砂。使用原位加速度计,我们可以测量撞击过程中的加速度曲线,并确定峰值加速度,碰撞持续时间和最大穿透深度。我们发现,穿透深度与碰撞速度成线性比例,但与所测试的实验范围无关,其有效重力与碰撞持续时间均与有效重力和碰撞速度均无关。在任何实验中均未观察到反弹。我们的低重力实验结果表明,与地面重力作用下的类似碰撞实验相比,碰撞能量要小两个数量级,从准静态状态向惯性状态的过渡会发生。较低的能量状态变化可能是由于在我们的实验中表面材料的流体动力学阻力增加,但也可能支持以下观点:准静态状态随着有效重力的降低而减小。
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