The rotational disruption of porous dust aggregates from ab-initio kinematic calculations

TL;DR

This study uses ab-initio kinematic calculations and N-body simulations to analyze how porous dust aggregates in space are disrupted by rapid rotation, revealing new insights into their deformation and stability.

Contribution

It introduces a detailed simulation approach to determine the rotational disruption threshold of porous dust aggregates, highlighting differences from theoretical models and effects of grain shape.

Findings

Disruption angular velocity $ imes 10^8 - 10^9$ rad/s predicted.

Large porous aggregates withstand rotation better than expected.

Rotation deforms grains into oblate shapes.

Abstract

Context: The sizes of dust in the interstellar medium follows a distribution where most of the dust mass is in smaller grains. However, the re-distribution from larger grains towards smaller sizes especially by means of rotational disruption is poorly understood. Aims: We aim to study the dynamics of porous grain aggregates under accelerated ration. Especially, we determine the deformation of the grains and the maximal angular velocity up to the rotational disruption event by caused by centrifugal forces. Methods: We pre-calculate aggregates my means of ballistic aggregation analogous to the interstellar dust as input for subsequent numerical simulations. In detail, we perform three-dimensional N-body simulations mimicking the radiative torque spin-up process up to the point where the grain aggregates become rotationally disrupted. Results: Our simulations results are in agreement with theoretical models predicting a characteristic angular velocity $\omega_{\mathrm{disr}}$ of the order of ${ 10^8 - 10^9\ \mathrm{rad\ s^{-1}} }$, where grains become rotationally disrupted. In contrast to theoretical predictions, we show that for large porous aggregates ($< 300\ \mathrm{nm}$) $\omega_{\mathrm{disr}}$ reaches a lower asymptotic value. Hence, such grains can withstand an accelerated ration more efficiently up to a factor of 10 because the displacement of mass by centrifugal forces and the subsequent mechanical deformation supports the buildup of new connections within the aggregate. Furthermore, we report that the rapid rotation of grains deforms an ensemble with initially 50:50 prolate and oblate shapes, respectively, preferentially into oblate shapes. Finally, we present a best fit formula to predict the average rotational disruption of an ensemble of porous dust aggregates dependent on internal grain structure, total number of monomers, and applied material properties.