2001.01728
The low-surface-brightness Universe: a new frontier in the study of galaxy evolution
Kaviraj
New and forthcoming deep-wide surveys, from instruments like the HSC, LSST and EUCLID, are poised to revolutionize our understanding of galaxy evolution, by revealing aspects of galaxies that are largely invisible in past wide-area datasets. These surveys will open up the realm of low-surface-brightness (LSB) and dwarf galaxies -- which dominate the galaxy number density -- for the first time at cosmological distances. They will also reveal key, unexplored LSB structures which strongly constrain our structure-formation paradigm, such as merger-induced tidal features and intra-cluster light. However, exploitation of these revolutionary new datasets will require us to address several data-analysis challenges. Data-processing pipelines will have to preserve LSB structures, which are susceptible to sky over-subtraction. Analysis of the prodigious data volumes will require machine-learning (in particular unsupervised techniques), to augment or even replace traditional methods. Cosmological simulations, which are essential for a statistical understanding of the physics of galaxy evolution, will require mass and spatial resolutions that are high enough to resolve LSB/dwarf galaxies and LSB structures. And finally, estimation of physical properties (e.g. stellar masses and star formation rates) will require reliable redshift information. Since it is unlikely that even next-generation spectrographs will provide complete spectral coverage in the LSB/dwarf regime outside the nearby Universe, photometric redshifts may drive the science from these datasets. It is necessary, therefore, that the accuracy of these redshifts is good enough (e.g. < 10 per cent) to enable statistical studies in the LSB/dwarf regime. I outline the tremendous discovery potential of new/forthcoming deep-wide surveys and describe techniques which will enable us to solve the data-analysis challenges outlined above. (Abridged)
2001.01746
The orbital histories of Magellanic Satellites using Gaia DR2 proper motions
Patel, Kallivayalil, et al
With the release of Gaia DR2, it is now possible to measure the proper motions (PMs) of the lowest mass, ultra-faint satellites in the Milky Way's (MW) halo for the first time. Many of these faint satellites are posited to have been accreted as satellites of the Magellanic Clouds (MCs). Using their 6D phase space information, we calculate the orbital histories of 13 ultra-faint satellites and five classical satellites in a combined MW+LMC+SMC potential to determine which galaxies are dynamically associated with the LMC/SMC. We identify three classes of galaxies that have recently interacted with the MCs: i.) MW satellites on high-speed orbits that made a close approach ($< 100$ kpc) to the MCs $< 1$ Gyr ago (Sculptor 1, Tucana 3, Segue 1); ii.) short-term Magellanic satellites that have completed one recent, close pericentric passage (Reticulum 2, Phoenix 2); and iii.) long-term Magellanic satellites that have completed two consecutive recent, close passages (Carina 2, Carina 3, Horologium 1, Hydrus 1). Results are reported for a range of MW and LMC masses. Contrary to previous work, we find no dynamical association between Carina, Fornax, and the MCs. We find that Aquarius 2, Canes Venatici 2, Crater 2, Draco 1, Draco 2, Hydra 2, and Ursa Minor are not members of the Magellanic system. Finally, we determine that the addition of the SMC's gravitational potential affects the longevity of satellites as members of the Magellanic system (short-term versus long-term satellites), but it does not change the total population of Magellanic satellites.
Observed mass-to-light ratios (M/L) of metal-rich globular clusters (GCs) disagree with theoretical predictions. This discrepancy is of fundamental importance since stellar population models provide the stellar masses that underpin most of extragalactic astronomy, near and far. We have derived radial velocities for 1,622 stars located in the centres of 59 Milky Way GCs - twelve of which have no previous kinematic information - using integral-field unit data from the WAGGS project. Using N-body models, we then determine dynamical masses and M/L ratios for the studied clusters. Our sample includes NGC 6528 and NGC 6553, which extend the metallicity range of GCs with measured M/L up to [Fe/H] ~ -0.1 dex. We find that metal-rich clusters have M/L more than two times lower than what is predicted by simple stellar population models. This confirms that the discrepant M/L-[Fe/H] relation remains a serious concern. We explore how our findings relate to previous observations, and the potential causes for the divergence, which we conclude is most likely due to dynamical effects.
The low-surface-brightness Universe: a new frontier in the study of galaxy evolution
Kaviraj
New and forthcoming deep-wide surveys, from instruments like the HSC, LSST and EUCLID, are poised to revolutionize our understanding of galaxy evolution, by revealing aspects of galaxies that are largely invisible in past wide-area datasets. These surveys will open up the realm of low-surface-brightness (LSB) and dwarf galaxies -- which dominate the galaxy number density -- for the first time at cosmological distances. They will also reveal key, unexplored LSB structures which strongly constrain our structure-formation paradigm, such as merger-induced tidal features and intra-cluster light. However, exploitation of these revolutionary new datasets will require us to address several data-analysis challenges. Data-processing pipelines will have to preserve LSB structures, which are susceptible to sky over-subtraction. Analysis of the prodigious data volumes will require machine-learning (in particular unsupervised techniques), to augment or even replace traditional methods. Cosmological simulations, which are essential for a statistical understanding of the physics of galaxy evolution, will require mass and spatial resolutions that are high enough to resolve LSB/dwarf galaxies and LSB structures. And finally, estimation of physical properties (e.g. stellar masses and star formation rates) will require reliable redshift information. Since it is unlikely that even next-generation spectrographs will provide complete spectral coverage in the LSB/dwarf regime outside the nearby Universe, photometric redshifts may drive the science from these datasets. It is necessary, therefore, that the accuracy of these redshifts is good enough (e.g. < 10 per cent) to enable statistical studies in the LSB/dwarf regime. I outline the tremendous discovery potential of new/forthcoming deep-wide surveys and describe techniques which will enable us to solve the data-analysis challenges outlined above. (Abridged)
2001.01746
The orbital histories of Magellanic Satellites using Gaia DR2 proper motions
Patel, Kallivayalil, et al
With the release of Gaia DR2, it is now possible to measure the proper motions (PMs) of the lowest mass, ultra-faint satellites in the Milky Way's (MW) halo for the first time. Many of these faint satellites are posited to have been accreted as satellites of the Magellanic Clouds (MCs). Using their 6D phase space information, we calculate the orbital histories of 13 ultra-faint satellites and five classical satellites in a combined MW+LMC+SMC potential to determine which galaxies are dynamically associated with the LMC/SMC. We identify three classes of galaxies that have recently interacted with the MCs: i.) MW satellites on high-speed orbits that made a close approach ($< 100$ kpc) to the MCs $< 1$ Gyr ago (Sculptor 1, Tucana 3, Segue 1); ii.) short-term Magellanic satellites that have completed one recent, close pericentric passage (Reticulum 2, Phoenix 2); and iii.) long-term Magellanic satellites that have completed two consecutive recent, close passages (Carina 2, Carina 3, Horologium 1, Hydrus 1). Results are reported for a range of MW and LMC masses. Contrary to previous work, we find no dynamical association between Carina, Fornax, and the MCs. We find that Aquarius 2, Canes Venatici 2, Crater 2, Draco 1, Draco 2, Hydra 2, and Ursa Minor are not members of the Magellanic system. Finally, we determine that the addition of the SMC's gravitational potential affects the longevity of satellites as members of the Magellanic system (short-term versus long-term satellites), but it does not change the total population of Magellanic satellites.
2001.01810
The WAGGS project -- III. Discrepant mass-to-light ratios of Galactic globular clusters at high metallicity
Dalgleish, et al
No comments:
Post a Comment