Galaxies infalling into groups: filaments vs. isotropic infall

TL;DR

This study compares galaxy properties during infall along filaments versus isotropic paths, revealing that filament galaxies experience stronger star formation quenching despite similar luminosity functions.

Contribution

It provides the first detailed comparison of galaxy properties in filamentary versus isotropic infall regions, highlighting the impact of filaments on star formation suppression.

Findings

Galaxies in filaments have higher fractions of low SSFR.

Luminosity functions are similar in filaments and isotropic infall regions.

Filament galaxies show stronger star formation quenching.

Abstract

We perform a comparative analysis of the properties of galaxies infalling into groups classifying them accordingly to whether they are: falling along filamentary structures; or they are falling isotropically. For this purpose, we identify filamentary structures connecting massive groups of galaxies in the SDSS. We perform a comparative analysis of some properties of galaxies in filaments, in the isotropic infall region, in the field, and in groups. We study the luminosity functions (LF) and the dependence of the specific star formation rate (SSFR) on stellar mass, galaxy type, and projected distance to the groups that define the filaments. We find that the LF of galaxies in filaments and in the isotropic infalling region are basically indistinguishable between them, with the possible exception of late-type galaxies. On the other hard, regardless of galaxy type, their LFs are clearly different from that of field or group galaxies. Both of them have characteristic absolute magnitudes and faint end slopes in between the field and group values. More significant differences between galaxies in filaments and in the isotropic infall region are observed when we analyse the SSFR. We find that galaxies in filaments have a systematically higher fraction of galaxies with low SSFR as a function of both, stellar mass and distance to the groups, indicating a stronger quenching of the star formation in the filaments compared to both, the isotropic infalling region, and the field. Our results suggest that some physical mechanisms that determine the differences observed between field galaxies and galaxies in systems, affect galaxies even when they are not yet within the systems.