The impact of stellar bars on quenching star formation: insights from a spatially resolved analysis in the local Universe

The impact of stellar bars on quenching star formation: insights from a spatially resolved analysis in the local Universe
Letizia Scaloni, Giulia Rodighiero, Andrea Enia, Carlotta Gruppioni, Francesca Annibali, Laura Bisigello, Paolo Cassata, Enrico Maria Corsini, Viviana Casasola, Cristina Maria Lofaro, Alessandro Bianchetti
arXiv:2404.11656v1 Announce Type: new
Abstract: Stellar bars are common morphological structures in the local Universe: according to optical and NIR surveys, they are present in about two-thirds of disc galaxies. These elongated structures are also believed to play a crucial role in secular evolutionary processes, since they are able to efficiently redistribute gas, stars and angular momentum within their hosts, although it remains unclear whether they enhance or suppress star formation. A useful tool to investigate such an ambiguity is the Main Sequence (MS) relation, which tightly links stellar mass ($M_{star}$) and star formation rate (SFR). The main goal of this work is to explore star formation processes in barred galaxies, in order to assess the relevance of possible bar quenching effects on the typical log-linear trend of the resolved MS. To this purpose, we carry out a spatially resolved analysis on sub-kpc scales for a sample of six nearby barred galaxies. Multi-wavelength photometric data (from far-UV to far-IR) are collected from the DustPedia database and a panchromatic Spectral Energy Distribution (SED) fitting procedure is applied on square apertures of fixed angular size (8″ $times$ 8″), making use of the magphys code. For each galaxy we obtain the distributions of stellar mass and star formation rate surface densities and relate them in the $log Sigma_{star}$ – $log Sigma_{rm SFR}$ plane deriving the spatially resolved MS relation. Although significant galaxy-to-galaxy variations are in place, we infer the presence of a common anti-correlation track in correspondence with the bar-hosting region, which shows systematically lower values of SFR. Such a central quiescent signature can be interpreted as the result of a bar-driven depletion of gas reservoirs and a consequent halt of star formation. This seems to point in the direction of an inside-out quenching scenario.arXiv:2404.11656v1 Announce Type: new
Abstract: Stellar bars are common morphological structures in the local Universe: according to optical and NIR surveys, they are present in about two-thirds of disc galaxies. These elongated structures are also believed to play a crucial role in secular evolutionary processes, since they are able to efficiently redistribute gas, stars and angular momentum within their hosts, although it remains unclear whether they enhance or suppress star formation. A useful tool to investigate such an ambiguity is the Main Sequence (MS) relation, which tightly links stellar mass ($M_{star}$) and star formation rate (SFR). The main goal of this work is to explore star formation processes in barred galaxies, in order to assess the relevance of possible bar quenching effects on the typical log-linear trend of the resolved MS. To this purpose, we carry out a spatially resolved analysis on sub-kpc scales for a sample of six nearby barred galaxies. Multi-wavelength photometric data (from far-UV to far-IR) are collected from the DustPedia database and a panchromatic Spectral Energy Distribution (SED) fitting procedure is applied on square apertures of fixed angular size (8″ $times$ 8″), making use of the magphys code. For each galaxy we obtain the distributions of stellar mass and star formation rate surface densities and relate them in the $log Sigma_{star}$ – $log Sigma_{rm SFR}$ plane deriving the spatially resolved MS relation. Although significant galaxy-to-galaxy variations are in place, we infer the presence of a common anti-correlation track in correspondence with the bar-hosting region, which shows systematically lower values of SFR. Such a central quiescent signature can be interpreted as the result of a bar-driven depletion of gas reservoirs and a consequent halt of star formation. This seems to point in the direction of an inside-out quenching scenario.