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Numerical Simulations of Laboratory‐Scale, Hypervelocity‐Impact Experiments for Asteroid‐Deflection Code Validation

Tané Remington, J. Michael Owen, A. Nakamura, Paul L. Miller, Megan Bruck Syal

2020Earth and Space Science21 citationsDOIOpen Access PDF

Abstract

Abstract Asteroids and comets have the potential to impact Earth and cause damage at the local to global scale. Deflection or disruption of a potentially hazardous object could prevent future Earth impacts, but due to our limited ability to perform experiments directly on asteroids, our understanding of the process relies upon large‐scale hydrodynamic simulations. Related simulations must be vetted through code validation by benchmarking against relevant laboratory‐scale, hypervelocity‐impact experiments. To this end, we compare simulation results from Spheral, an adaptive smoothed particle hydrodynamics code, to the fragment‐mass and velocity data from the 1991 two‐stage light gas‐gun impact experiment on a basalt sphere target, conducted at Kyoto University by Nakamura and Fujiwara. We find that the simulations are sensitive to the selected strain models, strength models, and material parameters. We find that, by using appropriate choices for these models in conjunction with well‐constrained material parameters, the simulations closely resemble with the experimental results. Numerical codes implementing these model and parameter selections may provide new insight into the formation of asteroid families (Michel et al., 2015, https://doi.org/10.2458/azu_uapress_9780816532131‐ch018 ) and predictions of deflection for the Double Asteroid Redirection mission (Stickle et al., 2017, https://doi.org/10.1016/j.proeng.2017.09.763 ).

Topics & Concepts

AsteroidHypervelocityDeflection (physics)Aerospace engineeringSmoothed-particle hydrodynamicsCollisionComputer scienceGeologyPhysicsMechanicsAstrobiologyEngineeringAstronomyClassical mechanicsComputer securityAstro and Planetary SciencePlanetary Science and ExplorationHigh-Velocity Impact and Material Behavior