Self-gravity in fluid and particle systems is the primary mechanism for the creation of structure in the Universe on astronomical scales. The rapidly rotating Solar System-sized disks which orbit stars during the early phases of star and planet formation can be massive and thus susceptible to spontaneous growth of spiral distortions driven by disk self-gravity. These are called gravitational instabilities (GI's). They can be important sources of mass and angular momentum transport due to the long-range torques they generate; and, if strong enough, they may fragment the disk into bound lumps with masses in the range of gas giant planets and brown dwarfs. This research group has been using numerical 3D hydrodynamics techniques to study the growth and nonlinear behavior of GI's in disks around young stars. Our simulations have demonstrated the sensitivity of outcomes to the thermal physics of the disks and have helped to delineate conditions conducive to the formation of dense clumps. We are currently concentrating our efforts on determining how GI's affect the long-term evolution and appearance of young stellar disks, with the hope of finding characteristic GI signatures by which we may recognize their occurrence in real systems and study them empirically.

Popular articles and press releases on our research:

• Rings Around the Stars by Hal Kibbey for Research & Creative Activity, IU.
• The Race is not to the Swift by Pickett & Lim for Astronomy & Geophysics.
• Safe Havens for Planetary Formation in Universe Today.
• Meshed Theories Could Explain Planet Formation by Kelly Young for the New Scientist.
• 'Protected Areas' Where Planets Can Form in Spaceflight Now.
• Whirlpool Haven for Planetary Birth in NASA's Astrobiology Magazine.
• Planet Puzzle: Theorists Wrestle with How They're Built by Michael Schirber for Space.com.
• New Theory Aims to Solve Gas Giant Puzzle in MSNBC.
• Jupiter's Formation Linked to That of Primitive Meteorites in Astrobiology.com.
• Giant Planet Birth Linked To That Of Primitive Meteorites in Spacedaily.com.
• Chondrules, by Jove! by Robert Adler for Astronomy.

Zoom of the inner disk showing density contrast; red is high density while blue is low.

Disk in perspective with star in the center.

Disk shown as it would appear through a mm-wavelength telescope.

Side view of a shocking wave in a protoplanetary disk responsible for chondrule production.

Last modified: May 5, 2006