Your search keyword '"Peterken, Thomas"' showing total 9 results

1. A direct test of density wave theory in a grand-design spiral galaxy

Author

Peterken, Thomas G., Merrifield, Michael R., Aragón-Salamanca, Alfonso, Drory, Niv, Krawczyk, Coleman M., Masters, Karen L., Weijmans, Anne-Marie, and Westfall, Kyle B.

Published

2019

2. SDSS-IV MaNGA: the chemical co-evolution of gas and stars in spiral galaxies.

Author

Greener, Michael J, Aragón-Salamanca, Alfonso, Merrifield, Michael, Peterken, Thomas, Sazonova, Elizaveta, Haggar, Roan, Bizyaev, Dmitry, Brownstein, Joel R, Lane, Richard R, and Pan, Kaike

Subjects

GALAXY spectra, COEVOLUTION, STAR formation, GALACTIC evolution, STELLAR mass, SPIRAL galaxies, GASES

Abstract

We investigate archaeologically how the metallicity in both stellar and gaseous components of spiral galaxies of differing masses evolve with time, using data from the SDSS-IV MaNGA survey. For the stellar component, we can measure this evolution directly by decomposing the galaxy absorption-line spectra into populations of different ages and determining their metallicities. For the gaseous component, we can only measure the present-day metallicity directly from emission lines. However, there is a well-established relationship between gas metallicity, stellar mass, and star formation rate which does not evolve significantly with redshift; since the latter two quantities can be determined directly for any epoch from the decomposition of the absorption-line spectra, we can use this relationship to infer the variation in gas metallicity over cosmic time. Comparison of present-day values derived in this way with those obtained directly from the emission lines confirms the validity of the method. Application of this approach to a sample of 1619 spiral galaxies reveals how the metallicity of these systems has changed over the last 10 billion yr since cosmic noon. For lower-mass galaxies, both stellar and gaseous metallicity increase together, as one might expect in well-mixed fairly isolated systems. In higher-mass systems, the average stellar metallicity has not increased in step with the inferred gas metallicity, and actually decreases with time. Such disjoint behaviour is what one might expect if these more massive systems have accreted significant amounts of largely pristine gas over their lifetimes, and this material has not been well mixed into the galaxies. [ABSTRACT FROM AUTHOR]

Published

2022

3. Size, shade, or shape? The contribution of galaxies of different types to the star formation history of the Universe from SDSS-IV MaNGA.

Author

Peterken, Thomas, Aragón-Salamanca, Alfonso, Merrifield, Michael, Avila-Reese, Vladimir, Boardman, Nicholas F, Domínguez Sánchez, Helena, Bizyaev, Dmitry, Drory, Niv, Pan, Kaike, and Brownstein, Joel R

Subjects

*PHYSICAL cosmology, *STAR formation, *GALAXIES, *STELLAR mass, *STELLAR populations, *GALAXY formation

Abstract

By fitting stellar populations to the fourth generation of the Sloan Digital Sky Survey (SDSS-IV) Mapping Nearby Galaxies at Apache Point Observatory (MaNGA) survey observations of ∼7000 suitably weighted individual galaxies, we reconstruct the star formation history of the Universe, which we find to be in reasonable agreement with previous studies. Dividing the galaxies by their present-day stellar mass, we demonstrate the downsizing phenomenon, whereby the more massive galaxies hosted the most star formation at earlier times. Further dividing the galaxy sample by colour and morphology, we find that a galaxy's present-day colour tells us more about its historical contribution to the cosmic star formation history than its current morphology. We show that downsizing effects are greatest among galaxies currently in the blue cloud, but that the level of downsizing in galaxies of different morphologies depends quite sensitively on the morphological classification used, due largely to the difficulty in classifying the smaller low-mass galaxies from their ground-based images. Nevertheless, we find agreement that among galaxies with stellar masses |$M_{\star } \gt 6\times 10^{9}\, \mathrm{ M}_{\odot }$|⁠ , downsizing is most significant in spirals. However, there are complicating factors. For example, for more massive galaxies, we find that colour and morphology are predictors of the past star formation over a longer time-scale than in less massive systems. Presumably this effect is reflecting the longer period of evolution required to alter these larger galaxies' physical properties, but shows that conclusions based on any single property do not tell the full story. [ABSTRACT FROM AUTHOR]

Published

2021

4. SDSS-IV MaNGA: the 'G-dwarf problem' revisited.

Author

Greener, Michael J, Merrifield, Michael, Aragón-Salamanca, Alfonso, Peterken, Thomas, Andrews, Brett, and Lane, Richard R

Subjects

MILKY Way, GALAXY formation, HEAVY elements, STAR formation, DWARF stars, GALACTIC evolution, SPIRAL galaxies

Abstract

The levels of heavy elements in stars are the product of enhancement by previous stellar generations, and the distribution of this metallicity among the population contains clues to the process by which a galaxy formed. Most famously, the 'G-dwarf problem' highlighted the small number of low-metallicity G-dwarf stars in the Milky Way, which is inconsistent with the simplest picture of a galaxy formed from a 'closed box' of gas. It can be resolved by treating the Galaxy as an open system that accretes gas throughout its life. This observation has classically only been made in the Milky Way, but the availability of high-quality spectral data from SDSS-IV MaNGA and the development of new analysis techniques mean that we can now make equivalent measurements for a large sample of spiral galaxies. Our analysis shows that high-mass spirals generically show a similar deficit of low-metallicity stars, implying that the Milky Way's history of gas accretion is common. By contrast, low-mass spirals show little sign of a G-dwarf problem, presenting the metallicity distribution that would be expected if such systems evolved as pretty much closed boxes. This distinction can be understood from the differing timescales for star formation in galaxies of differing masses. [ABSTRACT FROM AUTHOR]

Published

2021

5. SDSS-IV MaNGA: when is morphology imprinted on galaxies?

Author

Peterken, Thomas, Merrifield, Michael, Aragón-Salamanca, Alfonso, Avila-Reese, Vladimir, Boardman, Nicholas F, Drory, Niv, and Lane, Richard R

Subjects

*GALAXIES, *STAR formation, *STELLAR populations, *STELLAR evolution, *FOSSILS

Abstract

It remains an open question as to how long ago the morphology that we see in a present-day galaxy was typically imprinted. Studies of galaxy populations at different redshifts reveal that the balance of morphologies has changed over time, but such snapshots cannot uncover the typical time-scales over which individual galaxies undergo morphological transformation, nor which are the progenitors of today's galaxies of different types. However, these studies also show a strong link between morphology and star formation rate (SFR) over a large range in redshift, which offers an alternative probe of morphological transformation. We therefore derive the evolution in SFR and stellar mass of a sample of 4342 galaxies in the SDSS-IV MaNGA survey through a stellar population 'fossil record' approach, and show that the average evolution of the population shows good agreement with known behaviour from previous studies. Although the correlation between a galaxy's contemporaneous morphology and SFR is strong over a large range of lookback times, we find that a galaxy's present-day morphology only correlates with its relatively recent (⁠|$\sim \! 2\, \textrm {Gyr}$|⁠) star formation history. We therefore find strong evidence that morphological transitions to galaxies' current appearance occurred on time-scales as short as a few billion years. [ABSTRACT FROM AUTHOR]

Published

2021

6. SDSS-IV MaNGA: spatially resolved dust attenuation in spiral galaxies.

Author

Greener, Michael J, Aragón-Salamanca, Alfonso, Merrifield, Michael R, Peterken, Thomas G, Fraser-McKelvie, Amelia, Masters, Karen L, Krawczyk, Coleman M, Boardman, Nicholas F, Boquien, Médéric, Andrews, Brett H, Brinkmann, Jonathan, and Drory, Niv

Subjects

DUST, SPIRAL galaxies, STELLAR populations, STELLAR spectra, STAR formation, DUST measurement

Abstract

Dust attenuation in star-forming spiral galaxies affects stars and gas in different ways due to local variations in dust geometry. We present spatially resolved measurements of dust attenuation for a sample of 232 such star-forming spiral galaxies, derived from spectra acquired by the SDSS-IV MaNGA survey. The dust attenuation affecting the stellar populations of these galaxies (obtained using full spectrum stellar population fitting methods) is compared with the dust attenuation in the gas (derived from the Balmer decrement). Both of these attenuation measures increase for local regions of galaxies with higher star formation rates; the dust attenuation affecting the stellar populations increases more so than the dust attenuation in the gas, causing the ratio of the dust attenuation affecting the stellar populations to the dust attenuation in the gas to decrease for local regions of galaxies with higher star formation rate densities. No systematic difference is discernible in any of these dust attenuation quantities between the spiral arm and interarm regions of the galaxies. While both the dust attenuation in the gas and the dust attenuation affecting the stellar populations decrease with galactocentric radius, the ratio of the two quantities does not vary with radius. This ratio does, however, decrease systematically as the stellar mass of the galaxy increases. Analysis of the radial profiles of the two dust attenuation measures suggests that there is a disproportionately high concentration of birth clouds (incorporating gas, young stars, and clumpy dust) nearer to the centres of star-forming spiral galaxies. [ABSTRACT FROM AUTHOR]

Published

2020

7. Time-slicing spiral galaxies with SDSS-IV MaNGA.

Author

Peterken, Thomas, Fraser-McKelvie, Amelia, Aragón-Salamanca, Alfonso, Merrifield, Michael, Kraljic, Katarina, Knapen, Johan H, Riffel, Rogério, Brownstein, Joel, and Drory, Niv

Subjects

*GALAXY spectra, *STELLAR populations, *STAR formation, *AGE of stars, *DISTRIBUTION of stars, *SPIRAL galaxies

Abstract

Spectra of galaxies contain a wealth of information about the stellar populations from which they are made. With integral field unit (IFU) surveys, such data can be used to map out stellar population properties across the face of a galaxy, allowing one to go beyond simple radial profiles and study details of non-axisymmetric structure. To-date, however, such studies have been limited by the quality of available data and the power of spectral analysis tools. We now take the next step and study the barred spiral galaxy MCG + 07-28-064 from observations obtained as part of the SDSS-IV MaNGA project. We find that we can decompose this galaxy into 'time slices,' which reveal the varying contributions that stars of differing ages make to its bar and spiral structure, offering new insight into the evolution of these features. We find evidence for the ongoing growth of the bar, including the most recent star formation on its leading edge, and for the underlying density wave responsible for spiral structure. This pilot study indicates that there is a wealth of untapped information on the spatial distribution of star formation histories available in the current generation of IFU galaxy surveys. [ABSTRACT FROM AUTHOR]

Published

2019

8. SDSS-IV MaNGA: stellar population gradients within barred galaxies.

Author

Fraser-McKelvie, Amelia, Merrifield, Michael, Aragón-Salamanca, Alfonso, Peterken, Thomas, Masters, Karen, Krawczyk, Coleman, Andrews, Brett, Knapen, Johan H, Kruk, Sandor, Schaefer, Adam, Smethurst, Rebecca, Riffel, Rogério, Brownstein, Joel, and Drory, Niv

Subjects

STELLAR populations, SPIRAL galaxies, GALAXIES, GALACTIC evolution, STELLAR mass

Abstract

Bars in galaxies are thought to stimulate both inflow of material and radial mixing along them. Observational evidence for this mixing has been inconclusive so far, however, limiting the evaluation of the impact of bars on galaxy evolution. We now use results from the MaNGA integral field spectroscopic survey to characterize radial stellar age and metallicity gradients along the bar and outside the bar in 128 strongly barred galaxies. We find that age and metallicity gradients are flatter in the barred regions of almost all barred galaxies when compared to corresponding disc regions at the same radii. Our results re-emphasize the key fact that by azimuthally averaging integral field spectroscopic data one loses important information from non-axisymmetric galaxy components such as bars and spiral arms. We interpret our results as observational evidence that bars are radially mixing material in galaxies of all stellar masses, and for all bar morphologies and evolutionary stages. [ABSTRACT FROM AUTHOR]

Published

2019

9. SDSS-IV MaNGA: full spectroscopic bulge-disc decomposition of MaNGA early-type galaxies.

Author

Tabor, Martha, Merrifield, Michael, Aragón-Salamanca, Alfonso, Fraser-McKelvie, Amelia, Peterken, Thomas, Smethurst, Rebecca, Drory, Niv, and Lane, Richard R

Subjects

GALAXIES, GALACTIC bulges, STELLAR populations, DECOMPOSITION method, STELLAR mass, ANGULAR momentum (Mechanics)

Abstract

By applying spectroscopic decomposition methods to a sample of MaNGA early-type galaxies, we separate out spatially and kinematically distinct stellar populations, allowing us to explore the similarities and differences between galaxy bulges and discs, and how they affect the global properties of the galaxy. We find that the components have interesting variations in their stellar populations, and display different kinematics. Bulges tend to be consistently more metal rich than their disc counterparts, and while the ages of both components are comparable, there is an interesting tail of younger, more metal-poor discs. Bulges and discs follow their own distinct kinematic relationships, both on the plane of the stellar spin parameter, λ R , and ellipticity, ϵ, and in the relation between stellar mass, M *, and specific angular momentum, j *, with the location of the galaxy as a whole on these planes being determined by how much bulge and disc it contains. As a check of the physical significance of the kinematic decompositions, we also dynamically model the individual galaxy components within the global potential of the galaxy. The resulting components exhibit kinematic parameters consistent with those from the spectroscopic decomposition, and though the dynamical modelling suffers from some degeneracies, the bulges and discs display systematically different intrinsic dynamical properties. This work demonstrates the value in considering the individual components of galaxies rather than treating them as a single entity, which neglects information that may be crucial in understanding where, when, and how galaxies evolve into the systems we see today. [ABSTRACT FROM AUTHOR]

Published

2019