2005
DOI: 10.1017/s1743921305006782
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Physical and chemical properties of meteoroids as deduced from observations

Abstract: A review of the current knowledge of physical properties and chemical composition of meteoroids entering the Earth's atmosphere is presented. Meteoroid penetration ability, ablation coefficients, beginning heights, light curves, fragmentation, and spectra are considered. The inferred bulk densities, mechanical strengths, rotation, and atomic elemental abundances are discussed. Cometary meteoroids are effectively grain aggregates with low bulk density (100-1000 kg m −3), high porosity and low cohesivity. A vola… Show more

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Cited by 28 publications
(22 citation statements)
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“…The higher bulk density values have stony-iron meteorites (4-6 g/cm 3 ) and iron meteorites (4-8 g/cm 3 ) which are highly differentiated meteorites possibly representing cores of large asteroid parent bodies broken apart by catastrophic collisions. However such a high bulk density iron objects expected to be rare exception among observed meteors (Borovička, 2006). Consolmagno and Britt (1998) make a note that most meteorites are substantially denser than their suggested asteroid analogous which must have larger porosity because of presence of empty space on scales larger than the size of the meteorites.…”
Section: Application To the Real Phenomenamentioning
confidence: 94%
“…The higher bulk density values have stony-iron meteorites (4-6 g/cm 3 ) and iron meteorites (4-8 g/cm 3 ) which are highly differentiated meteorites possibly representing cores of large asteroid parent bodies broken apart by catastrophic collisions. However such a high bulk density iron objects expected to be rare exception among observed meteors (Borovička, 2006). Consolmagno and Britt (1998) make a note that most meteorites are substantially denser than their suggested asteroid analogous which must have larger porosity because of presence of empty space on scales larger than the size of the meteorites.…”
Section: Application To the Real Phenomenamentioning
confidence: 94%
“…The cometary meteoroid bulk density is consistent with the bulk density inferred for the several cometary nuclei (cf. Asphaug & Benz 1996;Davidson & Gutierrez 2004, 2005 suggesting microporosity could dominate cometary nucleus structure for HTC/NICs. However, we caution that most of these measurements are for Jupiter-family comets.…”
Section: Interpretation Of Meteoroid Physical Propertiesmentioning
confidence: 99%
“…Fragmentation also explains the production of the physical wake in meteor observations. Grains of different A&A 530, A113 (2011) masses, predicted by the dustball model, decelerate at different rates, leading to an elongated luminous region (Borovicka 2005). Many video meteors observed with short exposures show this wake (Fisher et al 2000).…”
Section: Introductionmentioning
confidence: 98%
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“…The IDP L2011K7 parent body was then probably a comet nucleus with small 'pebbles' (Rietmeijer, 2004a) without necessarily being a rubble-pile (Gombosi and Houpis, 1986;Weissman, 1986). Evidence for small-scale textural heterogeneity in comet nuclei exits in the form of cm-size meteoroids in comet debris trails (Ishiguro et al, 2002), meteors (Spurný and Borovicka, 1999) including the Perseids associated with Halley-type Comet 109P/ Swift-Tuttle (Koten and Borovička, 2001), and dense structurally coherent $1 mm cometary meteoroids (Borovička, 2006). The open space in CP IDPs was presumable filled with ice when resident in comet nuclei (Bradley and Brownlee, 1986).…”
Section: Partial Dehydration Of the Proto-phyllosilicatesmentioning
confidence: 99%