SURFS: Riding the waves with Synthetic UniveRses For Surveys

TL;DR

The SURFS simulations provide detailed, high-resolution N-body/Hydro data of the \\Lambda CDM cosmology, revealing properties and dynamics of haloes and subhaloes from early universe to today, with implications for galaxy formation.

Contribution

This work introduces the SURFS simulation suite with up to 10 billion particles, offering new insights into halo merger trees, subhalo dynamics, and mass functions at unprecedented scales and resolution.

Findings

Halo merger trees are numerically converged for halos with >100 particles.

Subhalo mass and velocity functions follow power-law distributions independent of redshift.

Subhaloes exhibit elliptical orbits with significant mass loss at pericenter.

Abstract

We present the Synthetic UniveRses For Surveys ({\sc surfs}) simulations, a set of N-body/Hydro simulations of the concordance $\Lambda$ Cold Dark Matter (\LCDM) cosmology. These simulations use Planck cosmology, contain up to 10 billion particles and sample scales & halo masses down to $1~$kpc & $10^8{\rm M}_\odot$. We identify and track haloes from $z=24$ to today using a state-of-the-art 6D halo finder and merger tree builder. We demonstrate that certain properties of halo merger trees are numerically converged for haloes composed of $\gtrsim100$ particles. Haloes smoothly grow in mass, $V_{\rm max}$, with the mass history characterised by $\log M(a)\propto\exp\left[-(a/\beta)^\alpha\right]$ where $a$ is the scale factor, $\alpha(M)\approx0.8$ \& $\beta(M)\approx0.024$, with these parameters decreasing with decreasing halo mass. Subhaloes follow power-law cumulative mass and velocity functions, i.e. $n(>f)\propto f^{-\alpha}$ with $\alpha_{M}=0.83\pm0.01$ and $\alpha_{V_{\rm max}}=2.13\pm0.03$ for mass \& velocity respectively, independent of redshift, as seen in previous studies. The halo-to-halo scatter in amplitude is $0.9$~dex. The number of subhaloes in a halo weakly correlates with a halo's concentration $c$ \& spin $\lambda$:haloes of high $c$ \& low $\lambda$ have $60\%$ more subhaloes than similar mass haloes of low $c$ \& high $\lambda$. High cadence tracking shows subhaloes are dynamic residents, with $25\%$ leaving their host halo momentarily, becoming a backsplash subhalo, and another $20\%$ changing hosts entirely, in agreement with previous studies. In general, subhaloes have elliptical orbits, $e\approx0.6$, with periods of $2.3^{+2.1}_{-1.7}$~Gyrs. Subhaloes lose most of their mass at pericentric passage with mass loss rates of $\sim40\%$~Gyr$^{-1}$. These catalogues will be made publicly available.