Towards a theoretical determination of the geographical probability distribution of meteoroid impacts on Earth [EPA]

http://arxiv.org/abs/1801.05720


Tunguska and Chelyabinsk impact events occurred inside a geographical area of only 3.4\% of the Earth’s surface. Although two events hardly constitute a statistically demonstration of a geographical pattern of impacts, their spatial coincidence is at least tantalizing. To understand if this concurrence reflects an underlying geographical and/or temporal pattern, we must aim at predicting the spatio-temporal distribution of meteoroid impacts on Earth. For this purpose we designed, implemented and tested a novel numerical technique, the “Gravitational Ray Tracing” (GRT) designed to compute the relative impact probability (RIP) on the surface of any planet. GRT is inspired by the so-called ray-casting techniques used to render realistic images of complex 3D scenes. In this paper we describe the method and the results of testing it at the time of large impact events. Our findings suggest a non-trivial pattern of impact probabilities at any given time on Earth. Locations at $60-90\deg$ from the apex are more prone to impacts, especially at midnight. Counterintuitively, sites close to apex direction has the lowest RIP, while in the antapex RIP are slightly larger than average. We present here preliminary maps of RIP at the time of Tunguska and Chelyabinsk events and found no evidence of a spatial or temporal pattern, suggesting that their coincidence was fortuitous. We apply the GRT method to compute theoretical RIP at the location and time of 394 large fireballs. Although the predicted spatio-temporal impact distribution matches marginally the observed events, we successfully predict their impact speed distribution.

Read this paper on arXiv…

J. Zuluaga and M. Sucerquia
Thu, 18 Jan 2018
51/58

Comments: 15 pages, 11 figures. Last stages of revision in MNRAS