Using Hydrodynamic Similarity as a Verification Method for Impact Cratering Simulations in the FLAG Hydrocode

IF 3.8 Q2 ASTRONOMY & ASTROPHYSICS
Matthew C. Holmes, Wendy K. Caldwell, Joanne L. Budzien and Carl E. Johnson
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引用次数: 0

Abstract

Hydrodynamic codes (hydrocodes) are common tools for modeling hypervelocity impacts to provide insight into the physical phenomenon. Hydrocodes can simulate impacts from micrometer to kilometer spatial scales and reach impact velocities difficult to achieve in experimental settings. However, numerical models are approximations, and demonstrating that a numerical method is capable of providing physical results for these models is essential. In this work, we employ a hydrocode verification technique that leverages hydrodynamic similarity, a mathematical property of the conservation equations of fluid mechanics that form the basis for hydrocode models. Using the FLAG hydrocode, we simulate aluminum (Al) and basalt projectiles and targets at spatial scales spanning 7 orders of magnitude (hundreds of micrometers to kilometers). These materials were chosen because Al-6061 is a common material in spacecraft and satellites and basalt is a useful approximation of rocky astronomical bodies. Our results show that hydrodynamic similarity holds for each material model used and across spatial scales. We show that under certain conditions hydrodynamic similarity can apply in the presence of gravity and that similarity does not hold in the presence of strength models. We conclude that the FLAG hydrocode preserves important mathematical properties of fluid dynamics in hypervelocity impacts of Al-6061 and basalt.
将水动力相似性作为 FLAG 水文编码中撞击塌陷模拟的验证方法
流体动力学代码(水力代码)是模拟超高速撞击的常用工具,可帮助人们深入了解物理现象。水动力代码可以模拟从微米到千米空间尺度的撞击,并达到在实验环境中难以实现的撞击速度。然而,数值模型只是近似值,因此必须证明数值方法能够为这些模型提供物理结果。在这项工作中,我们利用流体力学相似性这一流体力学守恒方程的数学特性,采用了一种水力代码验证技术,该技术构成了水力代码模型的基础。我们使用 FLAG 水文编码模拟了铝(Al)和玄武岩射弹和目标,其空间尺度跨越 7 个数量级(从数百微米到数千米)。之所以选择这些材料,是因为铝-6061 是航天器和卫星中的常见材料,而玄武岩则是岩石天体的有用近似材料。我们的研究结果表明,流体力学相似性适用于所使用的每种材料模型和不同的空间尺度。我们的结果表明,在某些条件下,流体力学相似性可适用于存在重力的情况,而在存在强度模型的情况下,相似性则不成立。我们的结论是,FLAG 流体动力学代码保留了 Al-6061 和玄武岩超高速撞击中流体动力学的重要数学特性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
The Planetary Science Journal
The Planetary Science Journal Earth and Planetary Sciences-Geophysics
CiteScore
5.20
自引率
0.00%
发文量
249
审稿时长
15 weeks
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