Periodic Reporting for period 4 - UFOS (Unveiling Planet Formation by Observations and Simulations)
Okres sprawozdawczy: 2022-12-01 do 2023-05-31
More specifically, the question that needs to be addressed is the level of gas turbulence in protoplanetary disks. The gas turbulence controls the transport of angular momentum and so the evolution of the disk. Another immediate goal of our project is the evolution of the dust component. How do larger dust grains evolve in the disk? Where do they concentrate and form the first proto-planets?
With the new dust module we have investigated the streaming instability for the first time in global simulations. Large dust pebbbles concentrate at the disk midplane and they locally dominate the mass content, which leads to a dust drag force back onto the gas. This drag gives rise to a new class of instabilities for which the streaming instability is a well-known candidate. In our results, we show that the streaming instability reaches a steady state in a case of inward drifting pebbles and a low level of turbulence.
Further our results for the first time combine the kinematics derived from 3D global hydrodynamical simulations of the vertical shear instability with line observations by the Atacama Large Millimeter Array. For that we post-processed the data with the radiative transfer code RADMC3D, we calculate the expect line emission for 12CO line emission. Using a model we could then subtract the Keplerian velocity from the observed line emission, estimating the emission surface and calculating the velocity profile at the emission surface. What remains is the residual map of the blue or red shifted line center, which corresponds directly to the velocity deviations. The results show for the first time that VSI turbulence can be observed with ALMA (Barraza et al. 2021).
In a follow-up work (Barraza 2023) we used the same framework to investigate for models with embedded planets. In this case, the planet can perturb the disk in addition to the vertical shear instability. The work showed that only very massive planets, like Jupiter mass planet produce perturbations in the velocity which can clearly be detected. Saturn mass planets on the other hand are more difficult to detect due to the interplay between VSI and the planet.
In another key work series (Delage et al. 2022,2023) we describe the disk evolution under a coupled framework of non-ideal MHD, viscous evolution by the magneto-rotational instability and non-ideal MHD terms coupled to the dust evolution. For the first time we can investigate for the formation of dust rings by the variations of the MHD efficiency in the protoplanetary disks. The results show a clear formation of rings in the regions between 10 to 100 au due to the dead-zone outer edge and the effect of dust grow. Small grains capture efficiently free electrons and so reduce the MRI activity while a depletion of grains favours for MRI turbulence.
Another project which was beyond the expected project was that we got access to observation of several protoplanetary disks with the MUSE instrument at the VLT. In the work (Flores et al. 2023) we observed for the first time disk driven magnetic winds and jets. In this work we investigated the inclination and position angle of the fast outflows and could relate them to the dust emission in the outer disk regions. This was a pioneer work showing for the first time the kinematics of spatial resolved disk winds.