Your search keyword '"Bryant, J. J."' showing total 4 results

1. The Colors of Bulges and Disks in the Core and Outskirts of Galaxy Clusters.

Author

Barsanti, S., Owers, M. S., McDermid, R. M., Bekki, K., Bryant, J. J., Croom, S. M., Oh, S., Robotham, A. S. G., Scott, N., and van de Sande, J.

Subjects

PHASE space, GALAXY formation, COLORS, CLUSTER sampling, GALAXIES, GALAXY clusters

Abstract

The role of the environment on the formation of S0 galaxies is still not well understood, specifically in the outskirts of galaxy clusters. We study eight low-redshift clusters, analyzing galaxy members up to cluster-centric distances of ∼2.5 R200. We perform 2D photometric bulge–disk decomposition in the g, r, and i bands from which we identify 469 double-component galaxies. We separately analyze the colors of the bulges and disks and their dependence on the projected cluster-centric distance and local galaxy density. For our sample of cluster S0 galaxies, we find that bulges are redder than their surrounding disks, show a significant color–magnitude trend, and have colors that do not correlate with environment metrics. On the other hand, the disks associated with our cluster S0s become significantly bluer with increasing cluster-centric radius but show no evidence for a color–magnitude relation. The disk color–radius relation is mainly driven by galaxies in the cluster core at 0 ≤ R/R200 < 0.5. No significant difference is found for the disk colors of backsplash and infalling galaxies in the projected phase space (PPS). Beyond R200, the disk colors do not change with the local galaxy density, indicating that the colors of double-component galaxies are not affected by preprocessing. A significant color–density relation is observed for single-component disk-dominated galaxies beyond R200. We conclude that the formation of cluster S0 galaxies is primarily driven by cluster core processes acting on the disks, while evidence of preprocessing is found for single-component disk-dominated galaxies. We publicly release the data from the bulge–disk decomposition. [ABSTRACT FROM AUTHOR]

Published

2021

2. The SAMI Galaxy Survey: Bulge and Disk Stellar Population Properties in Cluster Galaxies.

Author

Barsanti, S., Owers, M. S., McDermid, R. M., Bekki, K., Bland-Hawthorn, J., Brough, S., Bryant, J. J., Cortese, L., Croom, S. M., Foster, C., Lawrence, J. S., López-Sánchez, Á. R., Oh, S., Robotham, A. S. G., Scott, N., Sweet, S. M., and van de Sande, J.

Subjects

GALAXY clusters, STELLAR populations, GALAXY formation, STELLAR mass, GALAXIES, GALACTIC bulges

Abstract

We explore stellar population properties separately in the bulge and the disk of double-component cluster galaxies, to shed light on the formation of lenticular galaxies in dense environments. We study eight low-redshift clusters from the Sydney-AAO Multi-object Integral field Galaxy Survey, using two-dimensional photometric bulge–disk decomposition in the g, r, and i bands to characterize galaxies. For 192 double-component galaxies with M* > 1010M⊙, we estimate the color, age, and metallicity of the bulge and the disk. The analysis of the g − i colors reveals that bulges are redder than their surrounding disks, with a median offset of 0.12 ± 0.02 mag, consistent with previous results. To measure mass-weighted age and metallicity, we investigate three methods: (i) one based on galaxy stellar mass weights for the two components, (ii) one based on flux weights, and (iii) one based on radial separation. The three methods agree in finding 62% of galaxies having bulges that are 2–3 times more metal-rich than the disks. Of the remaining galaxies, 7% have bulges that are more metal-poor than the disks, while for 31%, the bulge and disk metallicities are not significantly different. We observe 23% of galaxies being characterized by bulges older and 34% by bulges younger with respect to the disks. The remaining 43% of galaxies have bulges and disks with statistically indistinguishable ages. Redder bulges tend to be more metal-rich than the disks, suggesting that the redder color in bulges is due to their enhanced metallicity relative to the disks instead of differences in stellar population age. [ABSTRACT FROM AUTHOR]

Published

2021

3. The Giant Radio Galaxy MRC B0319–454: Circumnuclear Structure of the Host Galaxy ESO 248-G10.

Author

Bryant, J. J. and Hunstead, R. W.

Published

2000

4. THE SAMI GALAXY SURVEY: TOWARD A UNIFIED DYNAMICAL SCALING RELATION FOR GALAXIES OF ALL TYPES.

Author

Cortese, L., Fogarty, L. M. R., Ho, I. -T, Bekki, K., Bland-Hawthorn, J., Colless, M., Couch, W., Croom, S. M., Glazebrook, K., Mould, J., Scott, N., Sharp, R., Tonini, C., Allen, J. T., Bloom, J., Bryant, J. J., Cluver, M., Davies, R. L., Drinkwater, M. J., and Goodwin, M.

Published

2014