2008
DOI: 10.5194/acp-8-7015-2008
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A chemical model of meteoric ablation

Abstract: Abstract. Most of the extraterrestrial dust entering the Earth's atmosphere ablates to produce metal vapours, which have significant effects on the aeronomy of the upper mesosphere and lower thermosphere. A new Chemical Ablation Model (CAMOD) is described which treats the physics and chemistry of ablation, by including the following processes: sputtering by inelastic collisions with air molecules before the meteoroid melts; evaporation of atoms and oxides from the molten particle; diffusion-controlled migratio… Show more

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Cited by 219 publications
(354 citation statements)
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“…The majority of the incoming particles are too small to 89 generate visually detectable meteoroids (particles need to be larger than 1 mm radius), but 90 ionization of the ablated atoms by hyperthermal collisions with atmospheric molecules 91 forms electrons which enable detection by radar, either through specular reflection from 92 the resulting electron trail or by incoherent scatter from the ball of electrons around the 93 meteoroid termed the head echo (e.g. (Janches, et al, 2009) Vondrak, et al, 2008). An unablated particle will then sediment through the 99 atmosphere under gravit E 100 general atmospheric circulation and eventually reach the surface, where it is termed a 101 micrometeorite (MM).…”
Section: Ablation On Atmospheric Entry 85mentioning
confidence: 99%
“…The majority of the incoming particles are too small to 89 generate visually detectable meteoroids (particles need to be larger than 1 mm radius), but 90 ionization of the ablated atoms by hyperthermal collisions with atmospheric molecules 91 forms electrons which enable detection by radar, either through specular reflection from 92 the resulting electron trail or by incoherent scatter from the ball of electrons around the 93 meteoroid termed the head echo (e.g. (Janches, et al, 2009) Vondrak, et al, 2008). An unablated particle will then sediment through the 99 atmosphere under gravit E 100 general atmospheric circulation and eventually reach the surface, where it is termed a 101 micrometeorite (MM).…”
Section: Ablation On Atmospheric Entry 85mentioning
confidence: 99%
“…Finally, only for the least sensitive MU radar results and utilizing an extreme revision of the widely used ionization probability, the high velocity meteors become the dominant population in the distribution even though they are the minority of the incoming flux. It is important to note that the only atmospheric parameter affecting the ablation is the atmospheric density profile experienced by the incoming meteoroid as shown in Vondrak et al (2008). While the ambient plasma density may have an impact on the formation of meteor trails, in particular the nonspecular ones , it does not affect the head echo.…”
Section: Discussionmentioning
confidence: 99%
“…This would be consistent with the MU and PFISR radar detections. Na and K are particularly of interest because, as volatiles, they are the elements that will ablate more easily off the meteoroid's body according to differential ablation (Vondrak et al 2008;Janches et al 2009), and the most likely candidates to produce enough electrons when particles are small and slow to make the meteors visible by a radar (see Paper I).…”
Section: Discussionmentioning
confidence: 99%
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