# The Coldest Place in the Universe: Probing the Ultra-Cold Outflow and   Dusty Disk in the Boomerang Nebula

**Authors:** R. Sahai, W.H.T. Vlemmings, and L-A. Nyman

arXiv: 1703.06929 · 2017-06-14

## TL;DR

The paper confirms the Boomerang Nebula as the coldest known object, revealing detailed structure and dynamics of its ultra-cold outflow and dusty disk, and suggests a binary interaction origin.

## Contribution

It provides new high-resolution observations of the ultra-cold outflow and dusty disk, and proposes a binary merger scenario for the nebula's formation.

## Key findings

- Ultra-cold outflow extends beyond 120,000 AU.
- Mass-loss rate increases with radius, proportional to r^{0.9-2.2}.
- Central waist contains large, cold dust grains.

## Abstract

Our Cycle 0 ALMA observations confirmed that the Boomerang Nebula is the coldest known object in the Universe, with a massive high-speed outflow that has cooled significantly below the cosmic background temperature. Our new CO 1-0 data reveal heretofore unseen distant regions of this ultra-cold outflow, out to $\gtrsim120,000$ AU. We find that in the ultra-cold outflow, the mass-loss rate (dM/dt) increases with radius, similar to its expansion velocity ($V$) - taking $V\propto r$, we find $dM/dt \propto r^{0.9-2.2}$. The mass in the ultra-cold outflow is $\gtrsim3.3$ Msun, and the Boomerang's main-sequence progenitor mass is $\gtrsim4$ Msun. Our high angular resolution ($\sim$0".3) CO J=3-2 map shows the inner bipolar nebula's precise, highly-collimated shape, and a dense central waist of size (FWHM) $\sim$1740 AU$\times275$ AU. The molecular gas and the dust as seen in scattered light via optical HST imaging show a detailed correspondence. The waist shows a compact core in thermal dust emission at 0.87-3.3 mm, which harbors $(4-7)\times10^{-4}$ Msun~of very large ($\sim$mm-to-cm sized), cold ($\sim20-30$ K) grains. The central waist (assuming its outer regions to be expanding) and fast bipolar outflow have expansion ages of $\lesssim1925$ yr and $\le1050$ yr: the "jet-lag" (i.e., torus age minus the fast-outflow age) in the Boomerang supports models in which the primary star interacts directly with a binary companion. We argue that this interaction resulted in a common-envelope configuration while the Boomerang's primary was an RGB or early-AGB star, with the companion finally merging into the primary's core, and ejecting the primary's envelope that now forms the ultra-cold outflow.

## Full text

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## Figures

13 figures with captions in the complete paper: https://tomesphere.com/paper/1703.06929/full.md

## References

44 references — full list in the complete paper: https://tomesphere.com/paper/1703.06929/full.md

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Source: https://tomesphere.com/paper/1703.06929