# The evolution of galaxy intrinsic alignments in the MassiveBlack II   universe

**Authors:** Aklant K Bhowmick, Yingzhang Chen, Ananth Tenneti, Tiziana Di Matteo,, Rachel Mandelbaum

arXiv: 1905.00906 · 2020-01-08

## TL;DR

This study examines how galaxy intrinsic alignments evolve over redshift using the MassiveBlackII simulation, revealing complex scale-dependent behaviors driven by dark matter and galaxy interactions.

## Contribution

It provides a detailed analysis of the redshift evolution of galaxy intrinsic alignments and their dependence on scale and subhalo properties in a cosmological simulation.

## Key findings

- Galaxy stellar components become less spherical over time.
- Galaxy-subhalo misalignment angle peaks at ~10 degrees with mild increase over redshift.
- Alignment between galaxies and dark matter subhaloes increases from z=3 to 0.6.

## Abstract

We investigate the redshift evolution of the intrinsic alignments (IA) of galaxies in the \texttt{MassiveBlackII} (MBII) simulation. We select galaxy samples above fixed subhalo mass cuts ($M_h>10^{11,12,13}~M_{\odot}/h$) at $z=0.6$ and trace their progenitors to $z=3$ along their merger trees. Dark matter components of $z=0.6$ galaxies are more spherical than their progenitors while stellar matter components tend to be less spherical than their progenitors. The distribution of the galaxy-subhalo misalignment angle peaks at $\sim10~\mathrm{deg}$ with a mild increase with time. The evolution of the ellipticity-direction~(ED) correlation amplitude $\omega(r)$ of galaxies (which quantifies the tendency of galaxies to preferentially point towards surrounding matter overdensities) is governed by the evolution in the alignment of underlying dark matter~(DM) subhaloes to the matter density of field, as well as the alignment between galaxies and their DM subhaloes. At scales $\sim1~\mathrm{cMpc}/h$, the alignment between DM subhaloes and matter overdensity gets suppressed with time, whereas the alignment between galaxies and DM subhaloes is enhanced. These competing tendencies lead to a complex redshift evolution of $\omega(r)$ for galaxies at $\sim1~\mathrm{cMpc}/h$. At scales $>1~\mathrm{cMpc}/h$, alignment between DM subhaloes and matter overdensity does not evolve significantly; the evolution of the galaxy-subhalo misalignment therefore leads to an increase in $\omega(r)$ for galaxies by a factor of $\sim4$ from $z=3$ to $0.6$ at scales $>1~\mathrm{cMpc}/h$. The balance between competing physical effects is scale dependant, leading to different conclusions at much smaller scales($\sim0.1~\mathrm{Mpc}/h$).

## Full text

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## Figures

14 figures with captions in the complete paper: https://tomesphere.com/paper/1905.00906/full.md

## References

45 references — full list in the complete paper: https://tomesphere.com/paper/1905.00906/full.md

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Source: https://tomesphere.com/paper/1905.00906