Your search keyword '"Leaman, Ryan"' showing total 8 results

1. Mapping Accreted Stars in Early-Type Galaxies Across the Mass-Size Plane

Author

Davison, Thomas, Norris, Mark, Leaman, Ryan, Kuntschner, Harald, Boecker, Alina, van de Ven, Glenn, Davison, Thomas, Norris, Mark, Leaman, Ryan, Kuntschner, Harald, Boecker, Alina, and van de Ven, Glenn

Abstract

Galaxy mergers are instrumental in dictating the final mass, structure, stellar populations, and kinematics of galaxies. Cosmological galaxy simulations indicate that the most massive galaxies at z=0 are dominated by high fractions of ‘ex-situ’ stars, which formed first in distinct independent galaxies, and then subsequently merged into the host galaxy. Using spatially resolved MUSE spectroscopy we quantify and map the ex-situ stars in thirteen massive Early Type galaxies. We use full spectral fitting together with semi-analytic galaxy evolution models to isolate the signatures in the galaxies’ light which are indicative of ex-situ populations. Using the large MUSE field of view we find that all galaxies display an increase in ex-situ fraction with radius, with massive and more extended galaxies showing a more rapid increase in radial ex-situ fraction, (reaching values between ∼30% to 100% at 2 effective radii) compared to less massive and more compact sources (reaching between ∼5% to 40% ex-situ fraction within the same radius). These results are in line with predictions from theory and simulations which suggest ex-situ fractions should increase significantly with radius at fixed mass for the most massive galaxies.

Published

2021

2. Mapping Accreted Stars in Early-Type Galaxies Across the Mass-Size Plane

Author

Davison, Thomas, Norris, Mark, Leaman, Ryan, Kuntschner, Harald, Boecker, Alina, van de Ven, Glenn, Davison, Thomas, Norris, Mark, Leaman, Ryan, Kuntschner, Harald, Boecker, Alina, and van de Ven, Glenn

Abstract

Galaxy mergers are instrumental in dictating the final mass, structure, stellar populations, and kinematics of galaxies. Cosmological galaxy simulations indicate that the most massive galaxies at z=0 are dominated by high fractions of ‘ex-situ’ stars, which formed first in distinct independent galaxies, and then subsequently merged into the host galaxy. Using spatially resolved MUSE spectroscopy we quantify and map the ex-situ stars in thirteen massive Early Type galaxies. We use full spectral fitting together with semi-analytic galaxy evolution models to isolate the signatures in the galaxies’ light which are indicative of ex-situ populations. Using the large MUSE field of view we find that all galaxies display an increase in ex-situ fraction with radius, with massive and more extended galaxies showing a more rapid increase in radial ex-situ fraction, (reaching values between ∼30% to 100% at 2 effective radii) compared to less massive and more compact sources (reaching between ∼5% to 40% ex-situ fraction within the same radius). These results are in line with predictions from theory and simulations which suggest ex-situ fractions should increase significantly with radius at fixed mass for the most massive galaxies.

Published

2021

3. Is There a Fundamental Upper Limit to the Mass of a Star Cluster?

Author

Norris, Mark A., van de Ven, Glenn, Kannappan, Sheila J., Schinnerer, Eva, Leaman, Ryan, Norris, Mark A., van de Ven, Glenn, Kannappan, Sheila J., Schinnerer, Eva, and Leaman, Ryan

Abstract

The discovery around the turn of the millenium of a population of very massive (Mstar > 2 x 10^6 M⊙) compact stellar systems (CSS) with physical properties (radius, velocity dispersion, stellar mass etc.) that are intermediate between those of the classical globular cluster (GC) population and galaxies led to questions about their exact nature. Recently a consensus has emerged that these objects, usually called ultra compact dwarfs (UCDs), are a mass-dependent mixture of high mass star clusters and remnant nuclei of tidally disrupted galaxies. The existence of genuine star clusters with stellar masses >10^7 M⊙ naturally leads to questions about the upper mass limit of the star cluster formation process. In this work we compile a comprehensive catalog of compact stellar systems, and reinforce the evidence that the true ancient star cluster population has a maximum mass of Mstar ~ 5 x 10^7 M⊙, corresponding to a stellar mass at birth of close to 10^8 M⊙. We then discuss several physical and statistical mechanisms potentially responsible for creating this limiting mass.

Published

2019

4. A galaxy's accretion history unveiled from its integrated spectrum

Author

Boecker, Alina, Leaman, Ryan, van de Ven, Glenn, Norris, Mark A., Mackereth, Ted, Crain, Robert A., Boecker, Alina, Leaman, Ryan, van de Ven, Glenn, Norris, Mark A., Mackereth, Ted, and Crain, Robert A.

Abstract

We present a new method of quantifying a galaxy's accretion history from its integrated spectrum alone. Using full spectral fitting and calibrated regularization techniques we show how we can accurately derive a galaxy's mass distribution in age-metallicity space and further separate this into stellar populations from different chemical enrichment histories. By exploiting the fact that accreted lower mass galaxies will exhibit an offset to lower metallicities at fixed age compared to the in-situ stellar population, we quantify the fraction of light that comes from past merger events, that are long since mixed in phase-space and otherwise indistinguishable. Empirical age-metallicity relations (AMRs) parameterized for different galaxy masses are used to identify the accreted stellar populations and link them back to the progenitor galaxy's stellar mass. This allows us to not only measure the host galaxy's total ex-situ mass fraction (facc), but also quantify the relative amount of accreted material deposited by satellite galaxies of different masses, i.e. the accreted satellite mass function in analogy to the subhalo mass function. Using mock spectra of simulated, present-day galaxies from the EAGLE suite we demonstrate that our method can recover the total accreted fraction to within ≈12%, the stellar mass of the most massive accreted subhalo to within ≈26% and the slope of the accreted satellite mass function to within ≈16% of the true values from the EAGLE merger trees. Future application of this method to observations could potentially provide us accretion histories of hundreds of individual galaxies, for which deep integrated light spectroscopy is available.

Published

2019

5. Is There a Fundamental Upper Limit to the Mass of a Star Cluster?

Author

Norris, Mark A., van de Ven, Glenn, Kannappan, Sheila J., Schinnerer, Eva, Leaman, Ryan, Norris, Mark A., van de Ven, Glenn, Kannappan, Sheila J., Schinnerer, Eva, and Leaman, Ryan

Abstract

The discovery around the turn of the millenium of a population of very massive (Mstar > 2 x 10^6 M⊙) compact stellar systems (CSS) with physical properties (radius, velocity dispersion, stellar mass etc.) that are intermediate between those of the classical globular cluster (GC) population and galaxies led to questions about their exact nature. Recently a consensus has emerged that these objects, usually called ultra compact dwarfs (UCDs), are a mass-dependent mixture of high mass star clusters and remnant nuclei of tidally disrupted galaxies. The existence of genuine star clusters with stellar masses >10^7 M⊙ naturally leads to questions about the upper mass limit of the star cluster formation process. In this work we compile a comprehensive catalog of compact stellar systems, and reinforce the evidence that the true ancient star cluster population has a maximum mass of Mstar ~ 5 x 10^7 M⊙, corresponding to a stellar mass at birth of close to 10^8 M⊙. We then discuss several physical and statistical mechanisms potentially responsible for creating this limiting mass.

Published

2019

6. A galaxy's accretion history unveiled from its integrated spectrum

Author

Boecker, Alina, Leaman, Ryan, van de Ven, Glenn, Norris, Mark A., Mackereth, Ted, Crain, Robert A., Boecker, Alina, Leaman, Ryan, van de Ven, Glenn, Norris, Mark A., Mackereth, Ted, and Crain, Robert A.

Abstract

We present a new method of quantifying a galaxy's accretion history from its integrated spectrum alone. Using full spectral fitting and calibrated regularization techniques we show how we can accurately derive a galaxy's mass distribution in age-metallicity space and further separate this into stellar populations from different chemical enrichment histories. By exploiting the fact that accreted lower mass galaxies will exhibit an offset to lower metallicities at fixed age compared to the in-situ stellar population, we quantify the fraction of light that comes from past merger events, that are long since mixed in phase-space and otherwise indistinguishable. Empirical age-metallicity relations (AMRs) parameterized for different galaxy masses are used to identify the accreted stellar populations and link them back to the progenitor galaxy's stellar mass. This allows us to not only measure the host galaxy's total ex-situ mass fraction (facc), but also quantify the relative amount of accreted material deposited by satellite galaxies of different masses, i.e. the accreted satellite mass function in analogy to the subhalo mass function. Using mock spectra of simulated, present-day galaxies from the EAGLE suite we demonstrate that our method can recover the total accreted fraction to within ≈12%, the stellar mass of the most massive accreted subhalo to within ≈26% and the slope of the accreted satellite mass function to within ≈16% of the true values from the EAGLE merger trees. Future application of this method to observations could potentially provide us accretion histories of hundreds of individual galaxies, for which deep integrated light spectroscopy is available.

Published

2019

7. A galaxy's accretion history unveiled from its integrated spectrum

Author

Boecker, Alina, Leaman, Ryan, van de Ven, Glenn, Norris, Mark A., Mackereth, Ted, Crain, Robert A., Boecker, Alina, Leaman, Ryan, van de Ven, Glenn, Norris, Mark A., Mackereth, Ted, and Crain, Robert A.

Abstract

We present a new method of quantifying a galaxy's accretion history from its integrated spectrum alone. Using full spectral fitting and calibrated regularization techniques we show how we can accurately derive a galaxy's mass distribution in age-metallicity space and further separate this into stellar populations from different chemical enrichment histories. By exploiting the fact that accreted lower mass galaxies will exhibit an offset to lower metallicities at fixed age compared to the in-situ stellar population, we quantify the fraction of light that comes from past merger events, that are long since mixed in phase-space and otherwise indistinguishable. Empirical age-metallicity relations (AMRs) parameterized for different galaxy masses are used to identify the accreted stellar populations and link them back to the progenitor galaxy's stellar mass. This allows us to not only measure the host galaxy's total ex-situ mass fraction (facc), but also quantify the relative amount of accreted material deposited by satellite galaxies of different masses, i.e. the accreted satellite mass function in analogy to the subhalo mass function. Using mock spectra of simulated, present-day galaxies from the EAGLE suite we demonstrate that our method can recover the total accreted fraction to within ≈12%, the stellar mass of the most massive accreted subhalo to within ≈26% and the slope of the accreted satellite mass function to within ≈16% of the true values from the EAGLE merger trees. Future application of this method to observations could potentially provide us accretion histories of hundreds of individual galaxies, for which deep integrated light spectroscopy is available.

Published

2019

8. On the early evolution of Local Group dwarf galaxy types: star formation and supernova feedback

Author

Bermejo-Climent, José R, Battaglia, Giuseppina, Gallart, Carme, Di Cintio, Arianna, Brook, Chris B, Cicuéndez, Luis, Monelli, Matteo; https://orcid.org/0000-0001-5292-6380, Leaman, Ryan, Mayer, Lucio, Peñarrubia, Jorge, Read, Justin I; https://orcid.org/0000-0002-1164-9302, Bermejo-Climent, José R, Battaglia, Giuseppina, Gallart, Carme, Di Cintio, Arianna, Brook, Chris B, Cicuéndez, Luis, Monelli, Matteo; https://orcid.org/0000-0001-5292-6380, Leaman, Ryan, Mayer, Lucio, Peñarrubia, Jorge, and Read, Justin I; https://orcid.org/0000-0002-1164-9302

Abstract

According to star formation histories (SFHs), Local Group dwarf galaxies can be broadly classified in two types: those forming most of their stars before zz = 2 (fast) and those with more extended SFHs (slow). The most precise SFHs are usually derived from deep but not very spatially extended photometric data; this might alter the ratio of old to young stars when age gradients are present. Here, we correct for this effect and derive the mass formed in stars by zz = 2 for a sample of 16 Local Group dwarf galaxies. We explore early differences between fast and slow dwarfs, and evaluate the impact of internal feedback by supernovae (SNe) on the baryonic and dark matter (DM) component of the dwarfs. Fast dwarfs assembled more stellar mass at early times and have larger amounts of DM within the half-light radius than slow dwarfs. By imposing that slow dwarfs cannot have lost their gas by zz = 2, we constrain the maximum coupling efficiency of SN feedback to the gas and to the DM to be ∼10 per cent. We find that internal feedback alone appears insufficient to quench the SFH of fast dwarfs by gas deprivation, in particular for the fainter systems. Nonetheless, SN feedback can core the DM halo density profiles relatively easily, producing cores of the sizes of the half-light radius in fast dwarfs by zz = 2 with very low efficiencies. Amongst the ‘classical’ Milky Way satellites, we predict that the smallest cores should be found in Draco and Ursa Minor, while Sculptor and Fornax should host the largest ones.

Published

2018