Roberto Gorelli points our attention at a recently published meteor related paper:

Discovery of a Meteor of Interstellar Origin

This article has been submitted by Amir Siraj and Abraham Loeb.


Abstract: The earliest confirmed interstellar object, ‘Oumuamua, was discovered in the Solar System by PanSTARRS in 2017, allowing for a calibration of the abundance of interstellar objects of its size ∼ 100 m. This was followed by the discovery of Borisov, which allowed for a similar calibration of its size ∼0.4−1 km. One would expect a much higher abundance of significantly smaller interstellar objects, with some of them colliding with Earth frequently enough to be noticeable. Based on the CNEOS catalog of bolide events, we identify the ∼ 0.45m meteor detected at 2014-01-08 17:05:34 UTC as originating from an unbound hyperbolic orbit with 99.999% confidence. The U.S. Department of Defense has since verified that “the velocity estimate reported to NASA is sufficiently accurate to indicate an interstellar trajectory.” We infer that the meteor had an asymptotic speed of v_∞ ∼ 42.1 ± 5.5 km/s outside of the solar system. Its origin is approximately towards R.A. 49.4° ± 4.1° and declination 11.2° ± 1.8°, implying that its initial velocity vector was 58±6 km/s away from the velocity of the Local Standard of Rest (LSR). Its high LSR speed implies a possible origin from the deep interior of a planetary system or a star in the thick disk of the Milky Way galaxy. The local number density of its population is 10^6 [+0.75 −1.5] AU^−3 or 9 × 10^21 [+0.75 −1.5] pc^-3 (necessitating 0.2 – 20 Earth masses of material to be ejected per local star). We show that the detections of CNEOS 2014-01-08, ‘Oumuamua, and Borisov collectively imply that the differential size distribution in good agreement with a collisional distribution, with a power-law slope is q ∼ 3.6 ± 0.5, where the quoted uncertainty corresponds to 2σ. We then consider the possibility of analyzing interstellar meteor compositions based on spectroscopy of their gaseous debris as they burn up in the Earth’s atmosphere. We propose a strategy for determining the orbits and chemical compositions of interstellar meteors, using a network of ∼ 600 all-sky camera systems to track and conduct remote spectroscopy on meteors larger than ∼ 5cm once every few years. It should also be possible to retrieve meteorites from the impact sites, providing the first samples of materials from other planetary systems.

You can download this paper for free: (6 pages).


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