A sharper view of Pal 5's tails: Discovery of stream perturbations with a novel non-parametric technique

TL;DR

This paper introduces a new non-parametric method to analyze stellar streams, revealing density perturbations in Pal 5's tails that suggest interactions with dark matter subhaloes, the Milky Way bar, and GMCs.

Contribution

The paper develops a novel probabilistic, adaptive, non-parametric technique for analyzing stellar stream density fluctuations, providing new insights into stream perturbations.

Findings

Detected multiple density bumps and gaps in Pal 5's stream.

Identified potential impacts from dark matter subhaloes of specific mass ranges.

Suggested Milky Way bar and GMCs as alternative perturbation sources.

Abstract

Only in the Milky Way is it possible to conduct an experiment which uses stellar streams to detect low-mass dark matter subhaloes. In smooth and static host potentials, tidal tails of disrupting satellites appear highly symmetric. However, perturbations from dark subhaloes, as well as from GMCs and the Milky Way bar, can induce density fluctuations that destroy this symmetry. Motivated by the recent release of unprecedentedly deep and wide imaging data around the Pal~5 stellar stream, we develop a new probabilistic, adaptive and non-parametric technique which allows us to bring the cluster's tidal tails into clear focus. Strikingly, we uncover a stream whose density exhibits visible changes on a variety of angular scales. We detect significant bumps and dips, both narrow and broad: two peaks on either side of the progenitor, each only a fraction of a degree across, and two gaps, $\sim2^{\circ}$ and $\sim9^{\circ}$ wide, the latter accompanied by a gargantuan lump of debris. This largest density feature results in a pronounced inter-tail asymmetry which cannot be made consistent with an unperturbed stream according to a suite of simulations we have produced. We conjecture that the sharp peaks around Pal 5 are epicyclic overdensities, while the two dips are consistent with impacts by subhaloes. Assuming an age of 3.4 Gyr for Pal 5, these two gaps would correspond to the characteristic size of gaps created by subhaloes in the mass range of $10^6-10^7 M_\odot$ and $10^7-10^8 M_\odot$ respectively. In addition to dark substructure, we find that the bar of the Milky Way can plausibly produce the asymmetric density seen in Pal 5 and that GMCs could cause the smaller gap.