We present the first high-resolution sub-mm survey of both dust and gas for a large population of protoplanetary disks. Characterizing fundamental properties of protoplanetary disks on a statistical level is critical to understanding how disks evolve into the diverse exoplanet population. We use ALMA to survey 89 protoplanetary disks around stars with M * > 0.1 M in the young (1-3 Myr), nearby (150-200 pc) Lupus complex. Our observations cover the 890 µm continuum and the 13 CO and C 18 O 3-2 lines. We use the sub-mm continuum to constrain M dust to a few Martian masses (0.2-0.4 M ⊕ ) and the CO isotopologue lines to constrain M gas to roughly a Jupiter mass (assuming ISM-like [CO]/[H 2 ] abundance). Of 89 sources, we detect 62 in continuum, 36 in 13 CO, and 11 in C 18 O at > 3σ significance. Stacking individually undetected sources limits their average dust mass to 6 Lunar masses (0.03 M ⊕ ), indicating rapid evolution once disk clearing begins. We find a positive correlation between M dust and M * , and present the first evidence for a positive correlation between M gas and M * , which may explain the dependence of giant planet frequency on host star mass. The mean dust mass in Lupus is 3× higher than in Upper Sco, while the dust mass distributions in Lupus and Taurus are statistically indistinguishable. Most detected disks have M gas 1 M Jup and gas-to-dust ratios < 100, assuming ISM-like [CO]/[H 2 ] abundance; unless CO is very depleted, the inferred gas depletion indicates that planet formation is well underway by a few Myr and may explain the unexpected prevalence of super-Earths in the exoplanet population.
Flattened, rotating disks of cool dust and gas extending for tens to hundreds
of AU are found around almost all low mass stars shortly after their birth.
These disks generally persist for several Myr, during which time some material
accretes onto the star, some is lost through outflows and photoevaporation, and
some condenses into centimeter- and larger-sized bodies or planetesimals.
Through observations mainly at infrared through millimeter wavelengths, we can
determine how common disks are at different ages, measure basic properties
including mass, size, structure, and composition, and follow their varied
evolutionary pathways. In this way, we see the first steps toward exoplanet
formation and learn about the origins of the Solar System. This review
addresses observations of the outer parts, beyond 1 AU, of protoplanetary disks
with a focus on recent infrared and (sub-)millimeter results and an eye to the
promise of new facilities in the immediate future.Comment: 65 pages, 11 figures, published in volume 49 of the Annual Review of
Astronomy and Astrophysics, based on the available literature up to the end
of 2010. We recommend that you retrieve the published paper from Annual
Reviews for greatly improved figures and typesettin
We present a sensitive, multiwavelength submillimeter continuum survey of 153 young stellar objects in the Taurus-Auriga star formation region. The submillimeter detection rate is 61% to a completeness limit of ∼10 mJy (3-σ) at 850 µm. The inferred circumstellar disk masses are log-normally distributed with a mean mass of ∼ 5 × 10 −3 M ⊙ and a large dispersion (0.5 dex). Roughly one third of the submillimeter sources have disk masses larger than the minimal nebula from which the solar system formed. The median disk to star mass ratio is 0.5%. The empirical behavior of the submillimeter continuum is best described as F ν ∝ ν 2.0±0.5 between 350 µm and 1.3 mm, which we argue is due to the combined effects of the fraction of optically thick emission and a flatter frequency behavior of the opacity compared to the interstellar medium. This latter effect could be due to a substantial population of large dust grains, which presumably would have grown through collisional agglomeration. In this sample, the only stellar property that is correlated with the outer disk is the presence of a companion. We find evidence for significant decreases in submillimeter flux densities, disk masses, and submillimeter continuum slopes along the canonical infrared spectral energy distribution evolution sequence for young stellar objects. The fraction of objects detected in the submillimeter is essentially identical to the fraction with excess nearinfrared emission, suggesting that dust in the inner and outer disk are removed nearly simultaneously.
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