Impact of planetesimal eccentricities and material strength on the appearance of eccentric debris disks

TL;DR

This study investigates how planetesimal eccentricities and material strength influence the observable features of eccentric debris disks, revealing that collisional parameters significantly affect brightness asymmetries and spectral characteristics.

Contribution

The paper introduces a combined simulation approach to analyze the effects of collisional parameters on debris disk appearance, highlighting the dominant role of material strength over dynamical excitation.

Findings

Higher dynamical excitation increases small particle production.

Lower material strength reduces brightness asymmetry, leading to apocenter glow.

Collisional parameters have a weak impact on the spectral energy distribution.

Abstract

Context: Since circumstellar dust in debris disks is short-lived, dust-replenishing requires the presence of a reservoir of planetesimals. These planetesimals in the parent belt of debris disks orbit their host star and continuously supply the disk with fine dust through their mutual collisions. Aims: We aim to understand effects of different collisional parameters on the observational appearance of eccentric debris disks. Methods: The collisional evolution of selected debris disk configurations was simulated with the numerical code ACE. Subsequently, selected observable quantities are simulated with our newly developed code DMS. The impact of the eccentricity, dynamical excitation, and the material strength is discussed with respect to the grain size distribution, the spectral energy distribution, and spatially resolved images of debris disk systems. Results: The most recognizable features in different collisional evolutions are as follows. First, both the increase of dynamical excitation in the eccentric belt of the debris disk system and the decrease of the material strength of dust particles result in a higher production rate of smaller particles. This reduces the surface brightness differences between the periastron and the apastron sides of the disks. For very low material strengths, the "pericenter glow" phenomenon is reduced and eventually even replaced by the opposite effect, the "apocenter glow". Second, it is possible to constrain the level of collisional activity from the appearance of the disk, for example, the wavelength-dependent apocenter-to-pericenter flux ratio. Within the considered parameter space, the impact of the material strength on the appearance of the disk is stronger than that of dynamical excitation of the system. Finally, we find that the impact of the collisional parameters on the net spectral energy distribution is weak.