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Main Authors: Gausmann, Evelise, Ferrari, Fabricio
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2407.02213
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author Gausmann, Evelise
Ferrari, Fabricio
author_facet Gausmann, Evelise
Ferrari, Fabricio
contents In this work, we use the theory of spatial networks to analyze galaxy distributions. The aim is to develop new approaches to study the spatial galaxy environment properties by means of the network parameters. We investigate how each of the network parameters (degree, closeness and betweeness centrality; diameter; giant component; transitivity) map the cluster structure and properties. We measure the network parameters of galaxy samples comprising the Coma Supercluster and 4 regions in their neighborhood ($z<0.0674$) using the catalog produced by \citet{tempel2014flux}. For comparison we repeat the same procedures for Random Geometric Graphs and Segment Cox process, generated with the same dimensions and mean density of nodes. We found that there is a strong correlation between degree centrality and the normalized environmental density. Also, at high degrees there are more elliptical than spiral galaxies, which confirms the density-morphology relation. The mean degree as a function of the connection radius is an estimator of the count-of-spheres and consequently provides the correlation dimension as a function of the connection radius. The correlation dimension indicates high clustering at scales indicated by the network diameter. Further, at this scales, high values of betweeness centrality characterize galaxy bridges connecting dense regions, tracing very well the filamentary structures. Then, since galaxies with the highest closeness centrality belongs to the largest components of the network, associated to supercluster regions, we can produce a catalog of superclusters only by extracting the largest connected components of the network. Establishing the correlation between the well-studied normalized environmental densities and the parameters of the network theory allows us to develop alternative tools to the study of the large-scale structures.
format Preprint
id arxiv_https___arxiv_org_abs_2407_02213
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Network Theory in Galaxy Distributions: The Coma Supercluster Neighborhood
Gausmann, Evelise
Ferrari, Fabricio
Cosmology and Nongalactic Astrophysics
Astrophysics of Galaxies
Computational Engineering, Finance, and Science
Computational Physics
In this work, we use the theory of spatial networks to analyze galaxy distributions. The aim is to develop new approaches to study the spatial galaxy environment properties by means of the network parameters. We investigate how each of the network parameters (degree, closeness and betweeness centrality; diameter; giant component; transitivity) map the cluster structure and properties. We measure the network parameters of galaxy samples comprising the Coma Supercluster and 4 regions in their neighborhood ($z<0.0674$) using the catalog produced by \citet{tempel2014flux}. For comparison we repeat the same procedures for Random Geometric Graphs and Segment Cox process, generated with the same dimensions and mean density of nodes. We found that there is a strong correlation between degree centrality and the normalized environmental density. Also, at high degrees there are more elliptical than spiral galaxies, which confirms the density-morphology relation. The mean degree as a function of the connection radius is an estimator of the count-of-spheres and consequently provides the correlation dimension as a function of the connection radius. The correlation dimension indicates high clustering at scales indicated by the network diameter. Further, at this scales, high values of betweeness centrality characterize galaxy bridges connecting dense regions, tracing very well the filamentary structures. Then, since galaxies with the highest closeness centrality belongs to the largest components of the network, associated to supercluster regions, we can produce a catalog of superclusters only by extracting the largest connected components of the network. Establishing the correlation between the well-studied normalized environmental densities and the parameters of the network theory allows us to develop alternative tools to the study of the large-scale structures.
title Network Theory in Galaxy Distributions: The Coma Supercluster Neighborhood
topic Cosmology and Nongalactic Astrophysics
Astrophysics of Galaxies
Computational Engineering, Finance, and Science
Computational Physics
url https://arxiv.org/abs/2407.02213