Astronomy and Astrophysics – Astrophysics
Scientific paper
2005-05-13
Astrophys.J. 626 (2005) L105-L108
Astronomy and Astrophysics
Astrophysics
5 pages, 3 color figures. Accepted for publication in ApJ Letters
Scientific paper
10.1086/431899
The disk around AU Microscopii, an M1 star in the Beta Pictoris Moving Group, is extraordinarily well-suited for comparison to the Beta Pic debris disk (type A5V). We use far-UV absorption spectroscopy of AU Mic to probe its edge-on disk for small amounts of molecular hydrogen, the primary constituent of gas giant planets. Our conservative upper limit on the line-of-sight H_2 column density is 1.7 x 10^{19} cm^{-2}, which is 18.5 times lower than the limit obtained from non-detection of sub-mm CO emission (Liu et al. 2004). In addition, there is a hint of H_2 absorption at a column density an order of magnitude or more below our upper limit. The H_2-to-dust ratio in the AU Mic disk is < 6:1, similar to that in the Beta Pic disk. This shows that the primordial gas has largely been dissipated in less than about 12 Myr for both disks, despite their very different stellar masses and luminosities. It is extremely difficult to form a giant planet around AU Mic with current core-accretion scenarios in such a short time.
Feldman Paul D.
Redfield Seth
Roberge Aki
Weinberger Alycia J.
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