# Astro2020 Science White Paper: Construction of an L* Galaxy: the   Transformative Power of Wide Fields for Revealing the Past, Present and   Future of the Great Andromeda System

**Authors:** Karoline M. Gilbert, Erik J. Tollerud, Jay Anderson, Rachael L., Beaton, Eric F. Bell, Alyson Brooks, Thomas M. Brown, James Bullock, Jeffrey, L. Carlin, Michelle Collins, Andrew Cooper, Denija Crnojevic, Julianne, Dalcanton, Andres del Pino, Richard D'Souza, Ivanna Escala, Mark Fardal,, Andreea Font, Marla Geha, Puragra Guhathakurta, Evan Kirby, Geraint F. Lewis,, Jennifer L. Marshall, Nicolas F. Martin, Kristen McQuinn, Antonela Monachesi,, Ekta Patel, Molly S. Peeples, Annalisa Pillepich, Amanda C. N. Quirk, R., Michael Rich, S. Tony Sohn, Yuan-Sen Ting, Roeland P. van der Marel, Andrew, Wetzel, Benjamin F. Williams, Jennifer Wojno

arXiv: 1904.01074 · 2019-04-03

## TL;DR

This white paper emphasizes the transformative potential of wide field observational facilities in unraveling the complex formation history and structure of the Andromeda Galaxy (M31), providing insights into galaxy evolution.

## Contribution

It advocates for the development of wide field photometric and spectroscopic tools to study M31's merger history, stellar populations, and hierarchical formation in unprecedented detail.

## Key findings

- Wide field facilities will enable detailed chemo-dynamical analysis of M31.
- These observations will clarify M31's merger and star formation history.
- The approach will improve understanding of galaxy formation processes.

## Abstract

The Great Andromeda Galaxy (M31) is the nexus of the near-far galaxy evolution connection and a principal data point for near-field cosmology. Due to its proximity (780 kpc), M31 can be resolved into individual stars like the Milky Way (MW). Unlike the MW, we have the advantage of a global view of M31, enabling M31 to be observed with techniques that also apply to more distant galaxies. Moreover, recent evidence suggests that M31 may have survived a major merger within the last several Gyr, shaping the morphology of its stellar halo and triggering a starburst, while leaving the stellar disk largely intact. The MW and M31 thus provide complementary opportunities for in-depth studies of the disks, halos, and satellites of L* galaxies.   Our understanding of the M31 system will be transformed in the 2020s if they include wide field facilities for both photometry (HST-like sensitivity and resolution) and spectroscopy (10-m class telescope, >1 sq. deg. field, highly multiplexed, R~ 3000 to 6000). We focus here on the power of these facilities to constrain the past, present, and future merger history of M31, via chemo-dynamical analyses and star formation histories of phase-mixed stars accreted at early times, as well as stars in surviving tidal debris features, M31's extended disk, and intact satellite galaxies that will eventually be tidally incorporated into the halo. This will yield an unprecedented view of the hierarchical formation of the M31 system and the subhalos that built it into the L* galaxy we observe today.

## Full text

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## Figures

3 figures with captions in the complete paper: https://tomesphere.com/paper/1904.01074/full.md

## References

32 references — full list in the complete paper: https://tomesphere.com/paper/1904.01074/full.md

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Source: https://tomesphere.com/paper/1904.01074