The process of star formation is central to a broad range of astrophysical problems: the nature of the first stars in the universe; the distribution of stars we see today; and the planet-forming environment of the circumstellar disk. Research in the department uses the latest observational tools across the electromagnetic spectrum to understand gas dynamics, magnetohydrodynamics, dust properties, chemistry in disks and the interstellar medium, and stellar physics. In addition, extrasolar planets are being investigated theoretically through dynamical simulations and observationally through precision radial velocity surveys and long-baseline interferometric techniques.
We are also performing numerical simulations of star-forming regions and protoplanetary disks, with simulations linked to observations through three-dimensional radiative transfer models. We are exploring what determines the masses of stars, why star clusters form, how field massive stars form, whether all stars form with potential protoplanetary disks, and how and why these disks form planets.
Faculty
| Fred Adams | Nuria Calvet | John Monnier |
| Ted Bergin | Lee Hartmann | Sally Oey |
Research Scientists & Postdocs
| Alicia Aarnio | Cécile Favre | Joel Lamb |
| Fabien Baron | Laura Ingleby | Justin Neill |
| Fujun Du | Stefan Kraus | Ruud Visser |
Graduate Students
| Jaehan Bae | Nate Crockett | Rachael Roettenbacher |
| Jeb Bailey | Tina Hsu | Kamber Schwarz |
| Xiao Che | Melissa McClure | Jordan Zastrow |
| Ilse Cleeves |
Image Credit: NASA/JPL-Caltech/T. Pyle
