The Broken Similarity: Sinking and Merging of Dark Matter Subhalos Across Hierarchical Levels

TL;DR

This study uses a novel tracking method in simulations to analyze hierarchical dark matter subhalo mergers, revealing complex behaviors and biases that challenge the assumption of self-similarity in halo mergers.

Contribution

It introduces a phase-space based definition of resolved subhalo mergers and uncovers new insights into the dynamics and distribution of satellite-satellite mergers.

Findings

Over 90% of sinking events occur between adjacent subhalo levels.

Major mergers dominate resolved merger events.

Satellite-satellite mergers are more common in outer regions of the host.

Abstract

We investigate hierarchical mergers among subhalos within a $\Lambda$CDM simulation using the HBT+ subhalo finder. Unlike previous methods, HBT+ tracks subhalo evolution across hierarchy levels, identifying the coalescence of subhalo cores in phase-space as a ''sinking" event. This coalescence marks a distinct stalled phase in orbital decay, providing a physically motivated and natural definition of a resolved merger. Our main findings include: 1) Over 90% of sinking events occur between adjacent subhalo levels, while cross-level pathways arise from tidal stripping, group infall, and numerical constraints. 2) Resolved mergers are predominantly major mergers (mass ratios > 1:10), while the occurrence of minor mergers decreases with the dynamical age of the host halo. 3) Although deep-level subhalos have low mass ratios relative to the host halo, their high mass ratios relative to direct parents significantly boost merger statistics. Consequently, the satellite-satellite merger rate can rival or exceed the central-satellite rate at lower mass thresholds. 4) Satellite-satellite mergers are spatially biased toward the outer regions of the host, suggesting that the central tidal field suppresses their orbital decay. 5) A bidirectional sinking detection recovers 32% more sinking events than the original algorithm, revealing that child-dispersion-driven mergers are dominated by tidal heating at the final stage of sinking, while parent-dispersion-driven and doubly-identified events proceed primarily via orbital decay. Altogether, these results reveal a complex landscape of hierarchical satellite mergers that deviate from the self-similarity of host halo mergers, due to additional physical processes including dynamical friction and the scale-dependent halo growth history.