# Location, orbit and energy of a meteoroid impacting the moon during the   Lunar Eclipse of January 21, 2019

**Authors:** Jorge I. Zuluaga (SEAP/IF/UdeA), Matipon Tangmatitham (MTU), Pablo A., Cuartas-Restrepo (SEAP/IF/UdeA), Jonathan Ospina (CAMO/SAA), Fritz Pichardo, (ASTRODOM), Sergio A. Lopez (Astrosur/Orion/SAA), Karls Pena (ASTRODOM), J., Mauricio Gaviria-Posada (Obs.LaLoma)

arXiv: 1901.09573 · 2020-01-08

## TL;DR

This study analyzes a meteoroid impact on the Moon during the 2019 lunar eclipse using multi-source observations to determine impact location, energy, and orbit, demonstrating citizen science's valuable role in planetary impact research.

## Contribution

The paper introduces a novel method combining parallax, photometry, and gravitational ray tracing to estimate impact parameters of a lunar meteoroid from citizen science data.

## Key findings

- Impact location: lat -29.43°, lon -67.89°
- Impact speed: approximately 14 km/s
- Estimated crater size: about 9 meters

## Abstract

During lunar eclipse of January 21, 2019 a meteoroid impacted the Moon producing a visible light flash. The impact was witnessed by casual observers offering an opportunity to study the phenomenon from multiple geographical locations. We use images and videos collected by observers in 7 countries to estimate the location, impact parameters (speed and incoming direction) and energy of the meteoroid. Using parallax, we achieve determining the impact location at lat. $-29.43^{+0.30}_{-0.21}$, lon. $-67.89^{+0.07}_{-0.09}$ and geocentric distance as 356553 km. After devising and applying a photo-metric procedure for measuring flash standard magnitudes in multiple RGB images having different exposure times, we found that the flash, had an average G-magnitude $\langle G\rangle = 6.7\pm0.3$. We use gravitational ray tracing (GRT) to estimate the orbital properties and likely radiant of the impactor. We find that the meteoroid impacted the moon with a speed of $14^{+7}_{-6}$ km/s (70% C.L.) and at a shallow angle, $\theta < 38.2$ degrees. Assuming a normal error for our estimated flash brightness, educated priors for the luminous efficiency and object density, and using the GRT-computed probability distributions of impact speed and incoming directions, we calculate posterior probability distributions for the kinetic energy (median $K_{\rm med}$ = 0.8 kton), body mass ($M_{\rm med}$ = 27 kg) and diameter ($d_{\rm med}$ = 29 cm), and crater size ($D_{\rm med}$ = 9 m). If our assumptions are correct, the crater left by the impact could be detectable by prospecting lunar probes. These results arose from a timely collaboration between professional and amateur astronomers which highlight the potential importance of citizen science in astronomy.

## Full text

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## Figures

32 figures with captions in the complete paper: https://tomesphere.com/paper/1901.09573/full.md

## References

50 references — full list in the complete paper: https://tomesphere.com/paper/1901.09573/full.md

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Source: https://tomesphere.com/paper/1901.09573