info:eu-repo/semantics/article
The sparkling Universe: clustering of voids and void clumps
Fecha
2017-07Registro en:
Lares Harbin Latorre, Marcelo; Ruiz, Andrés Nicolás; Luparello, Heliana Estefanía; Ceccarelli, Maria Laura; Garcia Lambas, Diego Rodolfo; et al.; The sparkling Universe: clustering of voids and void clumps; Wiley Blackwell Publishing, Inc; Monthly Notices of the Royal Astronomical Society; 468; 4; 7-2017; 4822-4830
0035-8711
1745-3933
CONICET Digital
CONICET
Autor
Lares Harbin Latorre, Marcelo
Ruiz, Andrés Nicolás
Luparello, Heliana Estefanía
Ceccarelli, Maria Laura
Garcia Lambas, Diego Rodolfo
Paz, Dante Javier
Resumen
We analyse the clustering of cosmic voids using a numerical simulation and the main galaxy sample from the Sloan Digital Sky Survey. We take into account the classification of voids into two types that resemble different evolutionary modes: those with a rising integrated density profile (void-in-void mode, or R-type) and voids with shells (void-in-cloud mode, or S-type). The results show that voids of the same type have stronger clustering than the full sample. We use the correlation analysis to define void clumps, associations with at least two voids separated by a distance of at most the mean void separation. In order to study the spatial configuration of void clumps, we compute the minimal spanning tree and analyse their multiplicity, maximum length and elongation parameter. We further study the dynamics of the smaller sphere that encloses all the voids in each clump. Although the global densities of void clumps are different according to their member-void types, the bulk motions of these spheres are remarkably lower than those of randomly placed spheres with the same radii distribution. In addition, the coherence of pairwise void motions does not strongly depend on whether voids belong to the same clump. Void clumps are useful to analyse the large-scale flows around voids, since voids embedded in large underdense regions are mostly in the void-in-void regime, were the expansion of the larger region produces the separation of voids. Similarly, voids around overdense regions form clumps that are in collapse, as reflected in the relative velocities of voids that are mostly approaching.