2022
DOI: 10.3847/psj/ac3df5
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Dark-flight Estimates of Meteorite Fall Positions: Issues and a Case Study Using the Murrili Meteorite Fall

Abstract: Fireball networks are used to recover meteorites, with the context of orbits. Observations from these networks cover the bright flight, where the meteoroid is luminescent, but to recover a fallen meteorite, these observations must often be predicted forward in time to the ground to estimate an impact position. This dark-flight modeling is deceptively simple, but there is hidden complexity covering the precise interactions between the meteorite and the (usually active) atmosphere. We describe the method and app… Show more

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Cited by 9 publications
(7 citation statements)
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“…Using these atmosphere models, we can then propagate bright flight observations to the ground using the darkflight model of Towner et al. (2021). In Fig.…”
Section: Darkflight and Wind Modelingmentioning
confidence: 99%
“…Using these atmosphere models, we can then propagate bright flight observations to the ground using the darkflight model of Towner et al. (2021). In Fig.…”
Section: Darkflight and Wind Modelingmentioning
confidence: 99%
“…The 12:00 UTC wind model was used to predict where meteorites would land, based on the last observed bright flight state vector (see the Trajectory section), using the method of Towner et al. (2022; code openly available at https://github.com/desertfireballnetwork/DFN_darkflight). We create Monte Carlo clones by varying the final observed state vector within uncertainty (see the Trajectory section), as well as meteorite physical parameters such as mass, shape, and density (fixed at 2090 kg m −3 based on recovered meteorite properties King et al., 2022).…”
Section: Strewn Fieldmentioning
confidence: 99%
“…The vector r is the radius vector of the object in the Earthcentered inertial (ECI) coordinate system, whereas its norm is denoted as r. In addition, µ denotes the standard gravitational parameter of the Earth and m is the mass of the object. The symbol F D represents the atmospheric drag to the object and can be calculated via (Towner et al 2022):…”
Section: Flight Equations and Fragmentationmentioning
confidence: 99%