Abstract:
The Universe at the present epoch is found to be a network of matter over dense and under dense regions. Usually, the over dense regions are dominated by the dark-matter (DM) filaments where massive gravitationally bound structures such as groups and clusters of galaxies form at the nodes. At the cosmological timescales, the baryonic matter follows the flow of DM only, and together they form the cosmic web. To date, this picture of the Universe is best revealed through cosmological large-volume simulations and large-scale galaxy red shift surveys, in which, the most important step is the appropriate identification of structures. So far, these structures are identified using various group finding codes, mostly based on the friend of friends (FoF) or spherical over density (SO) algorithms. Although, the main purpose is to identify gravitationally bound structures, surprisingly, the mass information has hardly been used effectively by these codes. Moreover, while it is an established fact that the bound structures can best be formed at some particular mass over dense regions and practically the large-scale structures are barely spherical in shape, the methods used so far either constrain the over density or use the real unstructured geometry only. Even though these are key factors in the accurate determination of structures-mass information that can precisely constrain the cosmological models of the Universe, hardly any attempt has been made as yet to consider these important parameters together while formulating the grouping algorithms. In this paper, we present our proposed algorithm called the measure of increased tie with gravity order which takes care of all the above-mentioned relevant features and ensures the bound structures by means of physical quantities, mainly mass and the total energy information. Unlike the usual FoF method where a statistically chosen single linking length is used for all grouping elements, we introduced a novel concept of physically relevant arm length for each element depending on their individual gravity leading to a distinct linking length for each unique pair of elements. This proposed algorithm is thus fundamentally new such that, not only able to catch the gravitationally bound, real unstructured geometry very well, it does identify it roughly within a predefined physically motivated density threshold. Such a thing could not be simultaneously achieved before by any of the usual FoF or SO-based methods. We also demonstrate the unique ability of the code in the appropriate identification of structures, both from large volume cosmological simulations as well as from galaxy red shift surveys, highlighting the fact that it mitigates a few shortcomings of the basic FoF and SO algorithms and strengthens the foundation of clustering or halo-finding methods in general.