[63.18] Formation and Evolution of Planetary Systems (FEPS): Primordial Warm Dust Evolution From 3-30 Myr around Sun-like Stars

AAS 207th Meeting, 8-12 January 2006
Session 63 From Here to Eternity: The Spitzer Legacy Programs
Poster, Tuesday, 9:20am-6:30pm, January 10, 2006, Exhibit Hall

Previous | Session 63 | Next | Author Index | Block Schedule

[63.18] Formation and Evolution of Planetary Systems (FEPS): Primordial Warm Dust Evolution From 3-30 Myr around Sun-like Stars

M.D. Silverstone, M.R. Meyer (Steward Obs., U. Arizona), E.E. Mamajek (Harvard-Smithsonian CfA), D.C. Hines (Space Science Institute), L.A. Hillenbrand (Caltech), J. Najita (NOAO), I. Pascucci (Steward Obs., U. Arizona), J. Bouwman (MPIfA), J.S. Kim (Steward Obs., U. Arizona), J.M. Carpenter (Caltech), J.R. Stauffer (Spitzer Science Center), D.E. Backman (NASA-Ames), A. Moro-Martin (Princeton U.), T. Henning, S. Wolf (MPIfA), T.Y. Brooke, D.L. Padgett (Spitzer Science Center)

We present data obtained with the Infrared Array Camera (IRAC) aboard the Spitzer Space Telescope (Spitzer) for a sample of 74 young (t < 30 Myr old) Sun-like (0.7 < M_Star/M_Sun < 1.5) stars. These are a sub-set of the observations that comprise the Spitzer Legacy science program entitled the Formation and Evolution of Planetary Systems (FEPS). Using IRAC we study the fraction of young stars that exhibit 3.6-8.0 micron infrared emission in excess of that expected from the stellar photosphere, as a function of age from 3-30 Myr. The most straightforward interpretation of such excess emission is the presence of hot (300-1000K) dust in the inner regions (< 3 AU) of a circumstellar disk. Five out of the 74 young stars show a strong infrared excess, four of which have estimated ages of 3-10 Myr. While we detect excesses from 5 optically thick disks, and photospheric emission from the remainder of our sample, we do not detect any excess emission from optically thin disks at these wavelengths. We compare our results with accretion disk fractions detected in previous studies, and use the ensemble results to place additional constraints on the dissipation timescales for optically-thick, primordial disks.

This work is based in part on observations made with the Spitzer Space Telescope, which is operated by the Jet Propulsion Laboratory, California Institute of Technology under NASA contract 1407. FEPS is pleased to acknowledge support through NASA contracts 1224768, 1224634, 1224566 administered through JPL.

If you would like more information about this abstract, please follow the link to http://feps.as.arizona.edu. This link was provided by the author. When you follow it, you will leave the Web site for this meeting; to return, you should use the Back comand on your browser.

The author(s) of this abstract have provided an email address for comments about the abstract: murray@as.arizona.edu

Previous | Session 63 | Next