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DOI of the published article https://doi.org/10.1016/j.forsciint.2022.111264
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DOI of the published article https://doi.org/10.1016/j.forsciint.2022.111264
Computational ballistic analysis of the cranial shot to John F. Kennedy
DOI:
https://doi.org/10.31224/osf.io/tncy5Keywords:
assassination, bone and bullet fracture mechanics, cranial gunshot, FEM, finite element simulation, John F Kennedy, smoothed-particle hydrodynamics, SPHAbstract
Almost 60 years after the assassination of John F. Kennedy in 1963 the majority of Americans are still reluctant to believe the official reports of commissions from 1964 and again in 1976 that determined the direction of the shot resulting in the fatal head injury. Long-withheld, confidential government files released in 2017 reignited the controversy. The present investigation computationally simulated projectile-skull impacts from the direction specified in official reports and from three other directions. Detailed geometric models of the human head and ammunition, as well as known parameters from the assassination site served as the supportive base for analysis. Constitutive mathematical models for the impact of projectile material with skull tissues at supersonic speed were employed to analyze bone and bullet fragmentation mechanics. Simulated fracture characteristics of the bone and the bullet were compared with photographic and X-ray evidence. The most likely origin of the fatal shot was determined based on the degree of corresponding deformation and fragmentation between simulation and documented evidence. Computational corroboration could be established as physically consistent with high-speed impact from the rear, as established by the official commissions. Simulations of three other speculative shot origins did not correspond to the documented evidence.Downloads
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2021-03-29 — Updated on 2021-03-29
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