# Silicate features in the circumstellar envelopes of the Class~I binary   driving source of HH250

**Authors:** F. Comer\'on, B. Merin, B. Reipurth, H.-W. Yen

arXiv: 1906.08210 · 2019-08-21

## TL;DR

This study analyzes the silicate features in the circumstellar envelopes of a binary system, revealing distinct dust compositions and evolutionary stages in each component, likely influenced by their environments and possible multiplicity.

## Contribution

It provides the first detailed comparison of silicate features in the two components of HH250-IRS, highlighting differences in dust evolution and potential effects of binarity.

## Key findings

- NW component shows broad absorption with little structure.
- SE component exhibits crystalline silicate emission, indicating dust processing.
- Differences suggest varied circumstellar environments and possible binary influence.

## Abstract

We investigate the silicate feature of the two Class I components of HH250-IRS, a resolved binary system with a separation of $0''53$ driving a Herbig-Haro flow. Each component has its own circumstellar envelope, and the system is surrounded by a circumbinary disk. We have carried out low resolution spectroscopy in the 8-13$\mu$m range using VISIR at ESO's Very Large Telescope. The silicate features of both sources are clearly different. The NW component has a broad, smooth absorption profile lacking structure. The SE component shows the silicate feature in emission, with structure longwards of 9.5$\mu$m indicating the presence of crystalline dust in the dominant form of forsterite. The apparent lack of an absorption feature caused by foreground dust is probably due to the filling of the band with emission by amorphous silicates in the envelope of the object. Despite their virtually certain coevality, the differences in the components of the HH250-IRS binary are most likely due to markedly different circumstellar environments. The NW component displays an unevolved envelope, whereas dust growth and crystallization has taken place in the SE component. The weak or absent signatures of enstatite in the latter are fairly unusual among envelopes with crystalline dust, and we tentatively relate it to a possible wide gap or an inner truncation of the disk already hinted in previous observations by a drop in the $L'$-band flux, which might indicate that the SE component could actually be a very close binary. We speculate that the clear differences between the silicate feature spectra of both components of HH250-IRS may be due either to disk evolution sped up by multiplicity, or by accretion variability leading to episodes of crystal formation.

## Full text

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## Figures

2 figures with captions in the complete paper: https://tomesphere.com/paper/1906.08210/full.md

## References

35 references — full list in the complete paper: https://tomesphere.com/paper/1906.08210/full.md

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Source: https://tomesphere.com/paper/1906.08210