The hybrid disks: a search and study to better understand evolution of disks

TL;DR

This study investigates hybrid debris disks with low gas content using submillimeter observations, revealing their unique properties and suggesting they are in a transient evolutionary phase with faster dust dissipation.

Contribution

It provides new observational data on hybrid disks, increasing the sample size and sensitivity, and offers insights into their evolutionary status compared to other disk types.

Findings

Detected a tentative CO line around HD23642.

Found a correlation between CO emission and dust continuum.

Hybrid disks show an enhanced gas-to-dust flux ratio.

Abstract

The increased sensitivity of millimeter-wave facilities now makes possible the detection of low amounts of gas in debris disks. Some of the gas-rich debris disks harbor peculiar properties, with possible pristine gas and secondary generated dust. The origin of the gas in these hybrid disks is strongly debated and the current sample is too sparse to understand this phenomenon. More detections are necessary to increase the statistics on this population. Lying at the final stages of evolution of proto-planetary disks and at the beginning of the debris disk phase, these objects could provide new insight into the processes involved in the making of planetary systems. We carried out a deep survey of the 12CO(2-1) and 12CO(3-2) lines with the APEX and IRAM radiotelescopes in young debris disks selected according to hybrid disk properties. The survey is complemented with a bibliographic study of the ratio between the emission of the gas and the continuum (S_CO/F_cont) in CTTS, Herbig Ae, WTTS, hybrid, and debris disks. Our sub-mm survey comprises 25 stars, including 17 new targets, and we increase the sensitivity limit by a factor 2 on eight sources compared to similar published studies. We report a 4sigma tentative detection of a double-peaked 12CO(2-1) line around HD23642; an eclipsing binary located in the Pleiades. We also reveal a correlation between the emission of the CO gas and the dust continuum from CTTS, Herbig Ae and few debris disks. The observed trend of the gas to dust flux ratio suggests a concurrent dissipation of the dust and gas components. Hybrid disks systematically lie above this trend, suggesting that these systems may witness a transient phase, when the dust has evolved more rapidly than the gas, with a flux ratio S_CO/F_cont enhanced by a factor of between 10 and 100 compared to standard (proto-)planetary disks.