Evolutionary Stages and Disk Properties of Young Stellar Objects in the Perseus Cloud

Abstract

We investigated the evolutionary stages and disk properties of 211 Young stellar objects (YSOs) across the Perseus cloud by modeling the broadband optical to mid-infrared (IR) spectral energy distribution (SED). By exploring the relationships among the turnoff wave bands lambdaturnoff (longward of which significant IR excesses above the stellar photosphere are observed), the excess spectral index alphaexcess at lambda <~ 24 microns, and the disk inner radius Rin (from SED modeling) for YSOs of different evolutionary stages, we found that the median and standard deviation of alphaexcess of YSOs with optically thick disks tend to increase with lambdaturnoff, especially at lambdaturnoff >= 5.8 microns, whereas the median fractional dust luminosities Ldust/Lstar tend to decrease with lambdaturnoff. This points to an inside-out disk clearing of small dust grains. Moreover, a positive correlation between alphaexcess and Rin was found at alphaexcess > ~0 and Rin > ~10 × the dust sublimation radius Rsub, irrespective of lambdaturnoff, Ldust/Lstar and disk flaring. This suggests that the outer disk flaring either does not evolve synchronously with the inside-out disk clearing or has little influence on alphaexcess shortward of 24 microns. About 23% of our YSO disks are classified as transitional disks, which have lambdaturnoff >= 5.8 microns and Ldust/Lstar >10(-3). The transitional disks and full disks occupy distinctly different regions on the Ldust/Lstar vs. alphaexcess diagram. Taking Ldust/Lstar as an approximate discriminator of disks with (>0.1) and without (<0.1) considerable accretion activity, we found that 65% and 35% of the transitional disks may be consistent with being dominantly cleared by photoevaporation and dynamical interaction respectively. [abridged]