Mid-infrared spectroscopy of zodiacal emission with AKARI/IRC

TL;DR

This study uses AKARI/IRC mid-infrared spectroscopy to analyze zodiacal emission, revealing detailed mineral compositions and variations in interplanetary dust properties across different sky directions, which reflect diverse parent body origins.

Contribution

It provides detailed mineralogical analysis of zodiacal dust using high-quality spectra, highlighting spatial variations and implications for dust origins and properties.

Findings

IPD contains small silicate crystals, especially enstatite.

Variation in dust grain size and mineral composition across sky directions.

Higher ecliptic latitudes show increased small grains and different mineral ratios.

Abstract

Interplanetary dust (IPD) is thought to be recently supplied from asteroids and comets. Grain properties of the IPD can give us the information about the environment in the proto-solar system, and can be traced from the shapes of silicate features around 10 $\mu$m seen in the zodiacal emission spectra. We analyzed mid-IR slit-spectroscopic data of the zodiacal emission in various sky directions obtained with the Infrared Camera on board AKARI satellite. After we subtracted the contamination due to instrumental artifacts, we have successfully obtained high S/N spectra and have determined detailed shapes of excess emission features in the 9 -- 12 $\mu$m range in all the sky directions. According to a comparison between the feature shapes averaged over all directions and the absorption coefficients of candidate minerals, the IPD was found to typically include small silicate crystals, especially enstatite grains. We also found the variations in the feature shapes and the related grain properties among the different sky directions. From investigations of the correlation between feature shapes and the brightness contributions from dust bands, the IPD in dust bands seems to have the size frequency distribution biased toward large grains and show the indication of hydrated minerals. The spectra at higher ecliptic latitude showed a stronger excess, which indicates an increase in the fraction of small grains included in the line of sight at higher ecliptic latitudes. If we focus on the dependence of detailed feature shapes on ecliptic latitudes, the IPD at higher latitudes was found to have a lower olivine/pyroxene ratio for small amorphous grains. The variation of the mineral composition of the IPD in different sky directions may imply different properties of the IPD from different types of parent bodies, because the spatial distribution of the IPD depends on the type of the parent body.