Introducing a new multi-particle collision method for the evolution of dense stellar systems II. Core collapse

TL;DR

This paper presents a novel multi-particle collision method for simulating dense stellar systems, enabling large-scale, realistic core collapse studies of star clusters with up to one million stars, revealing new insights into core dynamics and structure.

Contribution

The paper introduces a new MPC-based simulation technique that scales linearly with N, allowing detailed, large-scale star cluster evolution studies including core collapse phenomena.

Findings

Confirmed power-law relation between core size and time to collapse

Identified non-monotonic dependence of collapse time on mass function slope

Observed core bounce and asymptotic density slope evolution

Abstract

In a previous paper we introduced a new method for simulating collisional gravitational $N$-body systems with linear time scaling on $N$, based on the Multi-Particle Collision (MPC) approach. This allows us to simulate globular clusters with a realistic number of stellar particles in a matter of hours on a typical workstation. We evolve star clusters containing up to $10^6$ stars to core collapse and beyond. We quantify several aspects of core collapse over multiple realizations and different parameters, while always resolving the cluster core with a realistic number of particles. We run a large set of N-body simulations with our new code. The cluster mass function is a power-law with no stellar evolution, allowing us to clearly measure the effects of the mass spectrum. Leading up to core collapse, we find a power-law relation between the size of the core and the time left to core collapse. Our simulations thus confirm the theoretical self-similar contraction picture but with a dependence on the slope of the mass function. The time of core collapse has a non-monotonic dependence on the slope, which is well fit by a parabola. This holds also for the depth of core collapse and for the dynamical friction timescale of heavy particles. Cluster density profiles at core collapse show a broken power law structure, suggesting that central cusps are a genuine feature of collapsed cores. The core bounces back after collapse, and the inner density slope evolves to an asymptotic value. The presence of an intermediate-mass black hole inhibits core collapse. We confirm and expand on several predictions of star cluster evolution before, during, and after core collapse. Such predictions were based on theoretical calculations or small-size direct $N$-body simulations. Here we put them to the test on MPC simulations with a much larger number of particles, allowing us to resolve the collapsing core.