Abstract
We analysed 44 fine-grained and scoriaceous micrometeorites. A bulk mid-IR spectrum (8–13μm) for each grain was collected and the entire micrometeorite population classified into 5 spectral groups, based on the positions of their absorption bands. Corresponding carbonaceous Raman spectra, textural observations from SEM-BSE and bulk geochemical data via EMPA were collected to aid in the interpretation of mid-IR spectra. The 5 spectral groups identified correspond to progressive thermal decomposition. Unheated hydrated chondritic matrix, composed predominantly of phyllosilicates, exhibit smooth, asymmetric spectra with a peak at ∼10μm. Thermal decomposition of sheet silicates evolves through dehydration, dehydroxylation, annealing and finally by the onset of partial melting. Both CI-like and CM-like micrometeorites are shown to pass through the same decomposition stages and produce similar mid-IR spectra. Using known temperature thresholds for each decomposition stage it is possible to assign a peak temperature range to a given micrometeorite. Since the temperature thresholds for decomposition reactions are defined by the phyllosilicate species and the cation composition and that these variables are markedly different between CM and CI classes, atmospheric entry should bias the dust flux to favour the survival of CI-like grains, whilst preferentially melting most CM-like dust. However, this hypothesis is inconsistent with empirical observations and instead requires that the source ratio of CI:CM dust is heavily skewed in favour of CM material. In addition, a small population of anomalous grains are identified whose carbonaceous and petrographic characteristics suggest in-space heating and dehydroxylation have occurred. These grains may therefore represent regolith micrometeorites derived from the surface of C-type asteroids. Since the spectroscopic signatures of dehydroxylates are distinctive, i.e. characterised by a reflectance peak at 9.0–9.5μm, and since the surfaces of C-type asteroids are expected to be heated via impact gardening, we suggest that future spectroscopic investigations should attempt to identify dehydroxylate signatures in the reflectance spectra of young carbonaceous asteroid families.
Highlights
We analysed 44 fine-grained and scoriaceous micrometeorites
Given the evidence above, which includes unusually low R1 Raman values - suggesting relatively low (
Upon impact with the Earth’s upper atmosphere, micrometeorites composed of hydrated phyllosilicates experience flash heating and thermal decomposition
Summary
We analysed 44 fine-grained and scoriaceous micrometeorites. A bulk mid-IR spectrum (8–13 lm) for each grain was collected and the entire micrometeorite population classified into 5 spectral groups, based on the positions of their absorption bands. Given that chondrite specimens are relatively rare, while FgMMs are abundant (Maurette et al, 1991) with collections amounting into the thousands of individual grains, MMs are important resources revealing the diversity among aqueously altered chondritic materials and potentially sample many more unique and unrepresented parent asteroids than their meteorite counterparts (Nesvornyet al., 2006; Gounelle et al, 2009) Both C1 and C2 populations of FgMMs are composed of phyllosilicates, either serpentine and/or saponite (Genge et al, 2001), which are observable under TEM and in XRD studies (Nakamura et al, 2001; Nozaki et al, 2006). The petrographic thermal decomposition of MMs is well-studied, the mid-IR spectroscopic signatures of MMs are relatively under studied
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