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Main Authors: Peña-Asensio, Eloy, Vida, Denis, Cnossen, Ingrid, Ferrer, Esteban
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2508.19745
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author Peña-Asensio, Eloy
Vida, Denis
Cnossen, Ingrid
Ferrer, Esteban
author_facet Peña-Asensio, Eloy
Vida, Denis
Cnossen, Ingrid
Ferrer, Esteban
contents Climate change is inducing a global atmospheric contraction above the tropopause (~10 km), leading to systematic decrease in neutral air density. The impact of climate change on small meteoroids has already been observed over the last two decades, with documented shifts in their ablation altitudes in the mesosphere (~50-85 km) and lower thermosphere (~85-120 km). This study evaluates the potential effect of these changes on meteorite-dropping fireballs, which typically penetrate the stratosphere (~10-50 km). As a case study, we simulate the atmospheric entry of the fragile Winchcombe carbonaceous chondrite under projected atmospheric conditions for the year 2100 assuming a moderate future emission scenario. Using a semi-empirical fragmentation and ablation model, we compare the meteoroid's light curve and deceleration under present and future atmospheric density profiles. The results indicate a modest variation of the ablation heights, with the catastrophic fragmentation occurring 300 m lower and the luminous flight terminating 190 m higher. The absolute magnitude peak remains unchanged, but the fireball would appear 0.5 dimmer above ~120 km. The surviving meteorite mass is reduced by only 0.1 g. Our findings indicate that century-scale variations in atmospheric density caused by climate change moderately influence bright fireballs and have a minimal impact on meteorite survival.
format Preprint
id arxiv_https___arxiv_org_abs_2508_19745
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Century-Scale Effect of Climate Change on Meteorite Falls
Peña-Asensio, Eloy
Vida, Denis
Cnossen, Ingrid
Ferrer, Esteban
Earth and Planetary Astrophysics
Climate change is inducing a global atmospheric contraction above the tropopause (~10 km), leading to systematic decrease in neutral air density. The impact of climate change on small meteoroids has already been observed over the last two decades, with documented shifts in their ablation altitudes in the mesosphere (~50-85 km) and lower thermosphere (~85-120 km). This study evaluates the potential effect of these changes on meteorite-dropping fireballs, which typically penetrate the stratosphere (~10-50 km). As a case study, we simulate the atmospheric entry of the fragile Winchcombe carbonaceous chondrite under projected atmospheric conditions for the year 2100 assuming a moderate future emission scenario. Using a semi-empirical fragmentation and ablation model, we compare the meteoroid's light curve and deceleration under present and future atmospheric density profiles. The results indicate a modest variation of the ablation heights, with the catastrophic fragmentation occurring 300 m lower and the luminous flight terminating 190 m higher. The absolute magnitude peak remains unchanged, but the fireball would appear 0.5 dimmer above ~120 km. The surviving meteorite mass is reduced by only 0.1 g. Our findings indicate that century-scale variations in atmospheric density caused by climate change moderately influence bright fireballs and have a minimal impact on meteorite survival.
title Century-Scale Effect of Climate Change on Meteorite Falls
topic Earth and Planetary Astrophysics
url https://arxiv.org/abs/2508.19745