# An ALMA Survey of Protoplanetary Disks in the $\sigma$ Orionis Cluster

**Authors:** Megan Ansdell, Jonathan P. Williams, Carlo F. Manara, Anna Miotello,, Stefano Facchini, Nienke van der Marel, Leonardo Testi, Ewine F. van Dishoeck

arXiv: 1703.08546 · 2017-05-24

## TL;DR

This ALMA survey of 92 protoplanetary disks in the $\sigma$ Orionis cluster reveals rapid dust dissipation and the rarity of giant planet formation within a few million years, highlighting the influence of external photoevaporation.

## Contribution

First high-sensitivity ALMA survey of dust and gas in $\sigma$ Orionis disks, providing new insights into disk evolution and planet formation timescales.

## Key findings

- Only 11 disks have dust mass >10 Earth masses.
- Dust masses decline with proximity to the O9 star.
- External photoevaporation influences disk dissipation.

## Abstract

The $\sigma$ Orionis cluster is important for studying protoplanetary disk evolution, as its intermediate age ($\sim$3-5 Myr) is comparable to the median disk lifetime. We use ALMA to conduct a high-sensitivity survey of dust and gas in 92 protoplanetary disks around $\sigma$ Orionis members with $M_{\ast}\gtrsim0.1 M_{\odot}$. Our observations cover the 1.33 mm continuum and several CO $J=2-1$ lines: out of 92 sources, we detect 37 in the mm continuum and six in $^{12}$CO, three in $^{13}$CO, and none in C$^{18}$O. Using the continuum emission to estimate dust mass, we find only 11 disks with $M_{\rm dust}\gtrsim10 M_{\oplus}$, indicating that after only a few Myr of evolution most disks lack sufficient dust to form giant planet cores. Stacking the individually undetected continuum sources limits their average dust mass to 5$\times$ lower than that of the faintest detected disk, supporting theoretical models that indicate rapid dissipation once disk clearing begins. Comparing the protoplanetary disk population in $\sigma$ Orionis to those of other star-forming regions supports the steady decline in average dust mass and the steepening of the $M_{\rm dust}$-$M_{\ast}$ relation with age; studying these evolutionary trends can inform the relative importance of different disk processes during key eras of planet formation. External photoevaporation from the central O9 star is influencing disk evolution throughout the region: dust masses clearly decline with decreasing separation from the photoionizing source, and the handful of CO detections exist at projected separations $>1.5$ pc. Collectively, our findings indicate that giant planet formation is inherently rare and/or well underway by a few Myr of age.

## Full text

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## Figures

17 figures with captions in the complete paper: https://tomesphere.com/paper/1703.08546/full.md

## References

115 references — full list in the complete paper: https://tomesphere.com/paper/1703.08546/full.md

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Source: https://tomesphere.com/paper/1703.08546