%0 Generic %1 veyrat2023voidfinding %A Veyrat, Dahlia %A Douglass, Kelly A. %A BenZvi, Segev %D 2023 %K algorithm finder void %T Void-Finding Systematics using Crossing Numbers %U http://arxiv.org/abs/2302.05469 %X We study how well void-finding algorithms identify cosmic void regions and whether we can quantitatively and qualitatively describe their biases by comparing the voids they find with dynamical information from the underlying matter distribution. Using the ORIGAMI algorithm to determine the number of dimensions along which dark matter particles have undergone shell-crossing (crossing number) in $N$-body simulations from the AbacusSummit simulation suite, we identify dark matter particles which have undergone no shell crossing as belonging to voids. We then find voids in the corresponding halo distribution using two different void-finding algorithms: VoidFinder and V$^2$, a ZOBOV-based algorithm. The resulting void catalogs are compared to the distribution of dark matter particles to examine how their crossing numbers depend on void proximity. While both algorithms' voids have a similar distribution of crossing numbers near their centers, we find that beyond 0.25 times the effective void radius, voids found by VoidFinder exhibit a stronger preference for particles with low crossing numbers than those found by V$^2$. We examine two possible methods of mitigating this difference in efficacy between the algorithms. While we are able to partially mitigate the ineffectiveness of V$^2$ by using distance from the void edge as a measure of centrality, we conclude that VoidFinder more reliably identifies dynamically-distinct regions of low crossing number.

@misc{veyrat2023voidfinding, abstract = {We study how well void-finding algorithms identify cosmic void regions and whether we can quantitatively and qualitatively describe their biases by comparing the voids they find with dynamical information from the underlying matter distribution. Using the ORIGAMI algorithm to determine the number of dimensions along which dark matter particles have undergone shell-crossing (crossing number) in $N$-body simulations from the AbacusSummit simulation suite, we identify dark matter particles which have undergone no shell crossing as belonging to voids. We then find voids in the corresponding halo distribution using two different void-finding algorithms: VoidFinder and V$^2$, a ZOBOV-based algorithm. The resulting void catalogs are compared to the distribution of dark matter particles to examine how their crossing numbers depend on void proximity. While both algorithms' voids have a similar distribution of crossing numbers near their centers, we find that beyond 0.25 times the effective void radius, voids found by VoidFinder exhibit a stronger preference for particles with low crossing numbers than those found by V$^2$. We examine two possible methods of mitigating this difference in efficacy between the algorithms. While we are able to partially mitigate the ineffectiveness of V$^2$ by using distance from the void edge as a measure of centrality, we conclude that VoidFinder more reliably identifies dynamically-distinct regions of low crossing number.}, added-at = {2023-02-14T09:03:23.000+0100}, author = {Veyrat, Dahlia and Douglass, Kelly A. and BenZvi, Segev}, biburl = {https://www.bibsonomy.org/bibtex/2b6c2195693ce54e7d6d303f64415e75a/quark75}, description = {Void-Finding Systematics using Crossing Numbers}, interhash = {d2aea918a8f804ae15bd503df7dcd602}, intrahash = {b6c2195693ce54e7d6d303f64415e75a}, keywords = {algorithm finder void}, note = {cite arxiv:2302.05469Comment: 11 pages, 5 figures, submitted to ApJ}, timestamp = {2023-02-14T09:03:23.000+0100}, title = {Void-Finding Systematics using Crossing Numbers}, url = {http://arxiv.org/abs/2302.05469}, year = 2023 }