A stellar prodigy has been spotted about 450 light-years away in a system called UX Tau A by NASA's Spitzer Space Telescope. Astronomers suspect this system's central sun-like star, which is just one million years old, may already be surrounded by young planets. Scientists hope the finding will provide insight into when planets began to form in our own solar system.
"This result is exciting because we see a gap, potentially carved out by planets, around a dusty sun-like star. In almost all other star systems of this age, we typically see a primordial disk a thick disk of dust, without any clearings" - Catherine Espaillat, a graduate student at the University of Michigan, Ann Arbor.
Prior to the Spitzer observations, Espaillat and her teammates knew that a sun-like star sat at the center of UX Tau A. Now, using the telescope's infrared spectrometer instrument, they have discerned details about the dusty disk swirling around the central star.
A stellar prodigy has been spotted about 450 light-years away in a system called UX Tau A by NASA's Spitzer Space Telescope. Astronomers suspect this system's central Sun-like star, which is just one million years old, may already be surrounded by young planets. Scientists hope the finding will provide insight into when planets began to form in our own solar system.
"This result is exciting because we see a gap, potentially carved out by planets, around a dusty Sun-like star. In almost all other star systems of this age, we typically see a primordial disk -- a thick disk of dust, without any clearings" - Catherine Espaillat, a graduate student at the University of Michigan, Ann Arbor.
Prior to the Spitzer observations, Espaillat and her teammates knew that a Sun-like star sat at the centre of UX Tau A. Now, using the telescope's infrared spectrometer instrument, they have discerned details about the dusty disk swirling around the central star. Such dusty disks are where planets are thought to be born. Dust grains clump together like snowballs to form larger rocks, and then the bigger rocks collide to form the cores of planets. When rocks revolve around their central star, they act like cosmic vacuum cleaners, picking up all the gas and dust in their path and creating gaps. Spitzer saw a gap in UX Tau A's disk that extends from 0.2 to 56 astronomical units (an astronomical unit is the distance between the sun and Earth). In our solar system, this gap would occupy the space between Mercury and Saturn. Espaillat notes that the formation of one or more planets could be responsible for carving out the gap. Although gaps have been detected in disks swirling around young stars before, Espaillat notes that UX Tau A is special because the gap is sandwiched between two thick disks of dust. An inner thick dusty disk hugs the central star, then, moving outward, there is a gap, followed by another thick doughnut-shaped disk. Other systems with gaps contain very little to no dust near the central star. In other words, those gaps are more like big holes in the centres of disks. Some scientists suspect that the holes could have been carved out by a process called photoevaporation. Photoevaporation occurs when radiation from the central star heats up the gas and dust around it to the point where it evaporates away. The fact that there is thick disk swirling extremely close to UX Tau A's central star rules out the photoevaporation scenario. If photoevaporation from the star played a role, then large amounts of dust would not be floating so close to the star.
"This finding definitely affects the way astronomers look at planet formation. Spitzer's infrared spectrometer was able to see a gap in this system, but future, more sensitive telescopes maybe able to search for Earth-like planets in UX Tau A" - Catherine Espaillat.
Her paper will be published in the December 2007 issue of Astrophysical Journal Letters. Other authors on the paper include Nuria Calvet, Jesus Hernández and Lee Hartmann, also from the University of Michigan; Paola D'Alessio of the Universidad Nacional Autónoma de México, Michoacán; Chunhua Qi of the Harvard-Smithsonian Institute for Astrophysics, Cambridge, Mass.; Elise Furlan of the NASA Astrobiology Institute at the University of California at Los Angeles; and Dan Watson of the University of Rochester, N.Y.
Title: On the Diversity of the Taurus Transitional Disks: UX Tau A & Lk Ca 15 Authors: C. Espaillat, N. Calvet, P. D'Alessio, J. Hernandez, C. Qi, L. Hartmann, E. Furlan, D. M. Watson
The recently recognized class of "transitional disk" systems consists of young stars with optically-thick outer disks but inner disks which are mostly devoid of small dust. Here we introduce a further class of "pre-transitional disks" with significant near-infrared excesses which indicate the presence of an optically thick inner disk separated from an optically thick outer disk; thus, the spectral energy distributions of pre-transitional disks suggest the incipient development of disk gaps rather than inner holes. In UX Tau A, our analysis of the Spitzer IRS spectrum finds that the near-infrared excess is produced by an inner optically thick disk and a gap of ~56 AU is present. The Spitzer IRS spectrum of LkCa 15 is suggestive of a gap of ~46 AU, confirming previous millimetre imaging. In addition, UX Tau A contains crystalline silicates in its disk at radii >~ 56 AU which poses a challenge to our understanding of the production of this crystalline material. In contrast, LkCa 15's silicates are amorphous and pristine. UX Tau A and LkCa 15 increase our knowledge of the diversity of dust clearing in low-mass star formation.