# Angular momentum evolution of galaxies over the past 10-Gyr: A MUSE and   KMOS dynamical survey of 400 star-forming galaxies from z=0.3-1.7

**Authors:** Mark Swinbank (Durham), Chris Harrison, James Trayford, Matthieu, Schaller, Ian Smail, Joop Schaye, Tom Theuns, Renske Smit, David Alexander,, Roland Bacon, Richard Bower, Thierry Contini, Rob Crain, Carlos de Breuck,, Roberto Decarli, Benoit Epinat, Michele Fumagalli, Michelle Furlong, Audrey, Galametz, Helen Johnson, Claudia Lagos, Johan Richard, Joel Vernet, Ray, Sharples, David Sobral, John Stott

arXiv: 1701.07448 · 2017-04-12

## TL;DR

This study investigates the evolution of galaxy angular momentum over the past 10 billion years, revealing how it influences galaxy stability, morphology, and dynamical support in star-forming galaxies at redshifts 0.3 to 1.7.

## Contribution

It provides the first large-scale dynamical analysis of galaxies across this redshift range, linking angular momentum to galaxy stability and morphology evolution.

## Key findings

- Galaxies with higher specific angular momentum are more stable and resemble local spirals.
- Angular momentum scales as (1+z)^(-1) at fixed mass, indicating evolution over cosmic time.
- High angular momentum galaxies are morphologically stable, while low angular momentum ones are turbulent and clumpy.

## Abstract

We present a MUSE and KMOS dynamical study 405 star-forming galaxies at redshift z=0.28-1.65 (median redshift z=0.84). Our sample are representative of star-forming, main-sequence galaxies, with star-formation rates of SFR=0.1-30Mo/yr and stellar masses M=10^8-10^11Mo. For 49+/-4% of our sample, the dynamics suggest rotational support, 24+/-3% are unresolved systems and 5+/-2% appear to be early-stage major mergers with components on 8-30kpc scales. The remaining 22+/-5% appear to be dynamically complex, irregular (or face-on systems). For galaxies whose dynamics suggest rotational support, we derive inclination corrected rotational velocities and show these systems lie on a similar scaling between stellar mass and specific angular momentum as local spirals with j*=J/M*\propto M^(2/3) but with a redshift evolution that scales as j*\propto M^{2/3}(1+z)^(-1). We identify a correlation between specific angular momentum and disk stability such that galaxies with the highest specific angular momentum, log(j*/M^(2/3))>2.5, are the most stable, with Toomre Q=1.10+/-0.18, compared to Q=0.53+/-0.22 for galaxies with log(j*/M^(2/3))<2.5. At a fixed mass, the HST morphologies of galaxies with the highest specific angular momentum resemble spiral galaxies, whilst those with low specific angular momentum are morphologically complex and dominated by several bright star-forming regions. This suggests that angular momentum plays a major role in defining the stability of gas disks: at z~1, massive galaxies that have disks with low specific angular momentum, appear to be globally unstable, clumpy and turbulent systems. In contrast, galaxies with high specific angular have evolved in to stable disks with spiral structures.

## Full text

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## Figures

16 figures with captions in the complete paper: https://tomesphere.com/paper/1701.07448/full.md

## References

90 references — full list in the complete paper: https://tomesphere.com/paper/1701.07448/full.md

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Source: https://tomesphere.com/paper/1701.07448