# A concordant scenario to explain FU Ori from deep centimeter and   millimeter interferometric observations

**Authors:** Hauyu Baobab Liu, Eduard I. Vorobyov, Ruobing Dong, Michael M. Dunham,, Michihiro Takami, Roberto Galv\'an-Madrid, Jun Hashimoto, \'Agnes K\'osp\'al,, Thomas Henning, Motohide Tamura, Luis F. Rodr\'iguez, Naomi Hirano, Yasuhiro, Hasegawa, Misato Fukagawa, Carlos Carrasco-Gonzalez, Marco Tazzari

arXiv: 1701.06531 · 2017-05-24

## TL;DR

This study uses high-resolution interferometric observations across multiple frequencies to analyze FU Ori, revealing complex emission mechanisms and proposing a model involving disk instability and ionization effects to explain its outburst behavior.

## Contribution

It provides a detailed multi-frequency observational analysis of FU Ori, introducing a new model involving disk gravitational instability and ionization effects to explain its accretion outburst.

## Key findings

- No evidence for thermal radio jets at 8-10 GHz.
- Emission at >29 GHz is from unresolved sources near FU Ori and FU Ori S.
- SED modeling suggests a combination of free-free and dust emission.

## Abstract

We resolved FU Ori at 29-37 GHz using the JVLA with $\sim$0$''$.07 resolution, and performed the complementary JVLA 8-10 GHz observations, the SMA 224 GHz and 272 GHz observations, and compared with archival ALMA 346 GHz observations to obtain the SEDs. Our 8-10 GHz observations do not find evidence for the presence of thermal radio jets, and constrain the radio jet/wind flux to at least 90 times lower than the expected value from the previously reported bolometric luminosity-radio luminosity correlation. The emission at $>$29 GHz may be dominated by the two spatially unresolved sources, which are located immediately around FU Ori and its companion FU Ori S, respectively. Their deconvolved radii at 33 GHz are only a few au. The 8-346 GHz SEDs of FU Ori and FU Ori S cannot be fit by constant spectral indices (over frequency). The more sophisticated models for SEDs suggest that the $>$29 GHz emission is contributed by a combination of free-free emission from ionized gas, and thermal emission from optically thick and optically thin dust components. We hypothesize that dust in the innermost parts of the disks ($\lesssim$0.1 au) has been sublimated, and thus the disks are no more well shielded against the ionizing photons. The estimated overall gas and dust mass based on SED modeling, can be as high as a fraction of a solar mass, which is adequate for developing disk gravitational instability. Our present explanation for the observational data is that the massive inflow of gas and dust due to disk gravitational instability or interaction with a companion/intruder, was piled up at the few au scale due to the development of a deadzone with negligible ionization. The piled up material subsequently triggered the thermal and the MRI instabilities when the ionization fraction in the inner sub-au scale region exceeded a threshold value, leading to the high protostellar accretion rate.

## Full text

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## Figures

20 figures with captions in the complete paper: https://tomesphere.com/paper/1701.06531/full.md

## References

52 references — full list in the complete paper: https://tomesphere.com/paper/1701.06531/full.md

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Source: https://tomesphere.com/paper/1701.06531