Spitzer Spectroscopy of Circumstellar Disks in the 5 Myr Old Upper Scorpius OB Association

TL;DR

This study uses Spitzer mid-infrared spectroscopy to analyze circumstellar disks in the 5 million-year-old Upper Scorpius OB association, revealing dust evolution, disk structure changes, and reduced accretion compared to younger regions.

Contribution

It provides detailed spectral analysis of disks at different stellar types and models inner disk radii, highlighting disk evolution over a few million years.

Findings

Silicate features are prevalent in late-type stars but absent in early-type stars.

Inner disk radii range from approximately 0.2 to 1.2 AU.

Lower accretion rates and infrared excesses compared to younger star-forming regions.

Abstract

We present mid-infrared spectra between 5.2 and 38 microns for 26 disk-bearing members of the ~5 Myr old Upper Scorpius OB association obtained with the Infrared Spectrograph onboard the Spitzer Space Telescope. We find clear evidence for changes in the spectral characteristics of dust emission between the early (B+A) and late-type (K+M) infrared excess stars. The early-type members exhibit featureless continuum excesses that become apparent redward of ~8 microns. In contrast, 10 and 20 micron silicate features are present in all but one of the late-type excess members of Upper Scorpius. The strength of silicate emission among late-type Upper Scorpius members is spectral type dependent, with the most prominent features being associated with K5-M2 type stars. By fitting the spectral energy distributions (SED) of a sample of low-mass stars with accretion disk models, we find that the SEDs are consistent with models having inner disk radii ranging from ~0.2 to 1.2 AU. Complementary high resolution optical spectra for the Upper Scorpius excess stars were examined for signatures of gaseous accretion. Of the 35 infrared excess stars identified in Upper Scorpius, only 7 (all late-type) exhibit signatures of accretion. Mass accretion rates for these stars range from ~1e-11 to 1e-9 solar masses/yr. Compared to Class II sources in Taurus-Auriga, the disk population in Upper Scorpius exhibits reduced levels of near and mid-infrared excess emission and an order of magnitude lower mass accretion rates. These results suggest that the disk structure has changed significantly over the 2-4 Myr in age separating these two stellar populations. The ubiquity of depleted inner disks in the Upper Scorpius excess sample implies that such disks are a common evolutionary pathway that persists for some time.