# Astro2020 Science White Paper: The Formation and Evolution of Multiple   Star Systems

**Authors:** John J. Tobin (NRAO), Marina Kounkel (University of Western, Washington), Stella Offner (University of Texas at Austin), Patrick Sheehan, (National Radio Astronomy Observatory), Doug Johnstone (NRC - Herzberg), S., Thomas Megeath (University of Toledo), Kaitlin M. Kratter (University of, Arizona), Ian Stephens (Harvard-Smithsonian Center for Astrophysics), Zhi-Yun, Li (University of Virginia), Sarah Sadavoy (Harvard-Smithsonian Center for, Astrophysics), Leslie Looney (University of Illinois), Joel Green (STSci),, Rob Gutermuth (University of Massachusetts), Will Fischer (STSci), Michael M., Dunham (SUNY - Fredonia), Yao-Lun Yang (University of Texas)

arXiv: 1904.08442 · 2019-04-19

## TL;DR

This white paper reviews recent progress in understanding multiple star system formation, emphasizing the need for advanced observational capabilities and simulations to unravel the origins of stellar multiplicity.

## Contribution

It highlights the advancements made with current telescopes and outlines future observational and technological developments needed to further study multiple star systems.

## Key findings

- Significant progress in characterizing protostar systems.
- Identification of key observational techniques for future research.
- Recognition of technological needs for advancing the field.

## Abstract

Significant advances have been made over the past decade in the characterization of multiple protostar systems, enabled by the Karl G. Jansky Very Large Array (VLA), high-resolution infrared observations with the Hubble Space Telescope, and ground-based facilities. To further understand the mechanism(s) of multiple star formation, a combination of statistics, high-angular resolution radio/millimeter continuum imaging, characterization of kinematic structure, magnetic fields via polarimetry, and comparison with numerical simulations are needed. Thus, understanding the origin of stellar multiplicity in different regimes of companion separation will soon be within reach. However, to overcome challenges that studies in this field are now confronted with, a range of new capabilities are required: a new millimeter/centimeter wave facility with 10 mas resolution at {\lambda}=1 cm, space-based near to far-infrared observatories, continued development of low to high resolution spectroscopy on 3m to 10m class telescopes, and an ELT-class telescope with near to mid-infrared imaging/spectroscopic capability.

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Source: https://tomesphere.com/paper/1904.08442