http://arxiv.org/abs/2304.05777
External FUV irradiation of protoplanetary disks has an important impact on their evolution and ability to form planets. However, nearby (<300 pc) star-forming regions lack sufficiently massive young stars, while the Trapezium Cluster and NGC 2024 have complicated star-formation histories and their O-type stars’ intense radiation fields ($>10^4\,G_0$) destroy disks too quickly to study this process in detail. We study disk mass loss driven by intermediate (10 – 1000 $G_0$) FUV radiation fields in L1641 and L1647, where it is driven by more common A0 and B-type stars. Using the large (N=873) sample size offered by the Survey of Orion Disks with ALMA (SODA), we search for trends in the median disk dust mass with FUV field strength across the region as a whole and in two separate regions containing a large number of irradiated disks. For radiation fields between 1 – 100 $G_0$, the median disk mass in the most irradiated disks drops by a factor $\sim 2$ over the lifetime of the region, while the 95th percentile of disk masses drops by a factor 4 over this range. This effect is present in multiple populations of stars, and localized in space, to within 2 pc of ionizing stars. We fit an empirical irradiation – disk mass relation for the first time: $M_{\rm{dust,median}} = -1.3^{+0.14}{-0.13} \log{10}(F_{\rm{FUV}} / G_0) + 5.2^{+0.18}_{-0.19}$. This work demonstrates that even intermediate FUV radiation fields have a significant impact on the evolution of protoplanetary disks.
S. Terwisga and A. Hacar
Thu, 13 Apr 23
22/59
Comments: Accepted to A&A Letters. 5 pages, 4 figures