Abstract
Abstract The Japanese Hayabusa spacecraft successfully carried out in situ observations of S-class asteroid 25143 Itokawa, including the surface major elemental analysis with the X-ray fluorescence spectrometer (XRSHayabusa). Our previous results for the X-ray experiments (Okada et al., 2006a) indicated that major elemental ratios of Mg/Si and Al/Si on the surface of Itokawa resemble ordinary LL- or L-chondrites more than any other meteorite analogues. In the NEAR Shoemaker observations of S-class asteroid 433 Eros, the results of X-ray fluorescence observations indicated the depletion of sulfur, probably reflecting impact-induced volatilization, photoor ion-induced sputtering at the surface, or the loss of FeS-rich materials due to partial melting. Here, we determined the elemental abundance of sulfur (S) on the surface of Itokawa, in addition to that of Mg, Al, and Si, and its regional variation using XRS-Hayabusa observations. In particular, we carefully corrected the fluctuation of solar X-rays, variation of surface geometry, and sensor response function in this analysis, and thus we believe that the results are more accurate than those of our previous report. In this study, the upper and lower limits for Mg/Si, Al/Si, and S/Si overlap those of meteorite analogues for ordinary chondrites or primitive achondrites. In terms of the major elemental composition, Itokawa is best classified as a ordinary chondrite or a primitive achondrite. Our models do not include the mineral mixing effects. With the effects, the abundance of sulfur is expected to be 30% lower than our results. Hence, we conclude that the abundance of sulfur on the surface of Itokawa is almost equal to or even lower than the average abundance in ordinary chondrites. Although the abundances for Mg and Si are globally homogeneous, best-fit or upper limits of mass fraction for Al and S vary in local areas. There is a negative correlation (−0.92) for Al/Si vs. S/Si in ten facets. In particular, the area with the lowest sulfur, accompanied with enriched aluminum, is found in Arcoona, close to a cratered area. Therefore, aluminum enrichment and sulfur depletion features may support events of partial melting on the parent body of Itokawa or aluminum-rich material impacts on the surface of Itokawa. In some areas, Itokawa has a brighter geometric albedo and color variation. Little altered, fresh material may be exposed in these portions of the surface. The sulfur abundance on the surface appears to vary between little and highly altered areas by space weathering. Thus, the sulfur regional variation in our result may reflect the heterogeneity of a surface altered by space weathering.
Highlights
The Japanese Hayabusa spacecraft successfully carried out in situ observations of asteroid 25143 Itokawa (Fujiwara et al, 2006)
We estimated the solar X-ray spectra as the X-ray exciting source and determined the major elemental abundance on the surface of Itokawa for ten areas, and we carefully corrected the fluctuation of solar X-rays, geometry variation of local areas, and sensor response function in ten spectra
We determined the elemental abundance for Mg and Si, and best-fit and upper limit abundances for Al and S in the ten equatorial areas of Itokawa
Summary
The Japanese Hayabusa spacecraft successfully carried out in situ observations of asteroid 25143 Itokawa (Fujiwara et al, 2006). The X-ray fluorescence spectrometer onboard Hayabusa (XRS-Hayabusa) observed X-ray emission from the surface of Itokawa which determined the elemental composition. The primary goal of XRS-Hayabusa is to determine a relationship between S-class asteroid Itokawa and known meteorite analogues classified in laboratory measurements, including a fundamental question of whether the asteroid is a parent body of meteorites or not. Results of Near Infrared Spectrometer onboard Hayabusa (NIRS-Hayabusa) have indicated that olivine/pyroxene composition ratios derived from about 1-μm absorption band are most similar to LL-chondrites (Abe et al, 2006). These results imply that the S-class asteroid Itokawa is a parent body of ordinary chondrites
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