Your search keyword '"Barat, Dilyar"' showing total 10 results

1. SH$\alpha$DE: Survey description and mass-kinematics scaling relations for dwarf galaxies

Author

Barat, Dilyar, D'Eugenio, Francesco, Colless, Matthew, Sweet, Sarah M., Groves, Brent, and Cortese, Luca

Subjects

Astrophysics - Astrophysics of Galaxies

Abstract

The Study of H$\alpha$ from Dwarf Emissions (SH$\alpha$DE) is a high spectral resolution (R=13500) H$\alpha$ integral field survey of 69 dwarf galaxies with stellar masses $10^6

Published

2020

2. The SAMI Galaxy Survey: mass-kinematics scaling relations

Author

Barat, Dilyar, D'Eugenio, Francesco, Colless, Matthew, Brough, Sarah, Catinella, Barbara, Cortese, Luca, Croom, Scott M., Medling, Anne M., Oh, Sree, van de Sande, Jesse, Sweet, Sarah M., Yi, Sukyoung K., Bland-Hawthorn, Joss, Bryant, Julia, Goodwin, Michael, Groves, Brent, Lawrence, Jon, Owers, Matt S., Richards, Samuel N., and Scott, Nicholas

Subjects

Astrophysics - Astrophysics of Galaxies

Abstract

We use data from the Sydney-AAO Multi-object Integral-field spectroscopy (SAMI) Galaxy Survey to study the dynamical scaling relation between galaxy stellar mass $M_*$ and the general kinematic parameter $S_K = \sqrt{K V_{rot}^2 + \sigma^2}$ that combines rotation velocity $V_{rot}$ and velocity dispersion $\sigma$. We show that the $\log M_* - \log S_K$ relation: (1)~is linear above limits set by properties of the samples and observations; (2)~has slightly different slope when derived from stellar or gas kinematic measurements; (3)~applies to both early-type and late-type galaxies and has smaller scatter than either the Tully-Fisher relation ($\log M_* - \log V_{rot}$) for late types or the Faber-Jackson relation ($\log M_* - \log\sigma$) for early types; and (4)~has scatter that is only weakly sensitive to the value of $K$, with minimum scatter for $K$ in the range 0.4 and 0.7. We compare $S_K$ to the aperture second moment (the `aperture velocity dispersion') measured from the integrated spectrum within a 3-arcsecond radius aperture ($\sigma_{3^{\prime\prime}}$). We find that while $S_{K}$ and $\sigma_{3^{\prime\prime}}$ are in general tightly correlated, the $\log M_* - \log S_K$ relation has less scatter than the $\log M_* - \log \sigma_{3^{\prime\prime}}$ relation., Comment: 14 pages, 8 figures, Accepted 2019 May 22. Received 2019 May 18; in original form 2019 January 6

Published

2019

3. The SAMI Galaxy Survey: Data Release Two with absorption-line physics value-added products

Author

Scott, Nicholas, van de Sande, Jesse, Croom, Scott M., Groves, Brent, Owers, Matt S., Poetrodjojo, Henry, D'Eugenio, Francesco, Medling, Anne M., Barat, Dilyar, Barone, Tania M., Bland-Hawthorn, Joss, Brough, Sarah, Bryant, Julia, Cortese, Luca, Foster, Caroline, Green, Andrew W., Oh, Sree, Colless, Matthew, Drinkwater, Michael J., Driver, Simon P., Goodwin, Michael, Gunawardhana, Madusha L. P., Federrath, Christoph, Harischandra, Lloyd, Jin, Yifei, Lawrence, J. S., Lorente, Nuria P., Mannering, Elizabeth, O'Toole, Simon, Richards, Samuel N., Sanchez, Sebastian F., Schaefer, Adam L., Sealey, Katrina, Sharp, Rob, Sweet, Sarah M., Taranu, Dan S., and Varidel, Mathew

Subjects

Astrophysics - Astrophysics of Galaxies

Abstract

We present the second major release of data from the SAMI Galaxy Survey. Data Release Two includes data for 1559 galaxies, about 50% of the full survey. Galaxies included have a redshift range 0.004 < z < 0.113 and a large stellar mass range 7.5 < log (M_star/M_sun) < 11.6. The core data for each galaxy consist of two primary spectral cubes covering the blue and red optical wavelength ranges. For each primary cube we also provide three spatially binned spectral cubes and a set of standardised aperture spectra. For each core data product we provide a set of value-added data products. This includes all emission line value-added products from Data Release One, expanded to the larger sample. In addition we include stellar kinematic and stellar population value-added products derived from absorption line measurements. The data are provided online through Australian Astronomical Optics' Data Central. We illustrate the potential of this release by presenting the distribution of ~350,000 stellar velocity dispersion measurements from individual spaxels as a function of R/R_e, divided in four galaxy mass bins. In the highest stellar mass bin (log (M_star/M_sun)>11), the velocity dispersion strongly increases towards the centre, whereas below log (M_star/M_sun)<10 we find no evidence for a clear increase in the central velocity dispersion. This suggests a transition mass around log (M_star/M_sun) ~10 for galaxies with or without a dispersion-dominated bulge., Comment: 22 pages, 14 figures. Accepted for publication in MNRAS. See the SAMI Data Release 2 website (https://sami-survey.org/abdr) for current status. The data can be accessed via Australian Astronomical Optics' Data Central service (https://datacentral.org.au/)

Published

2018

4. The Taipan Galaxy Survey: Scientific Goals and Observing Strategy

Author

da Cunha, Elisabete, Hopkins, Andrew M., Colless, Matthew, Taylor, Edward N., Blake, Chris, Howlett, Cullan, Magoulas, Christina, Lucey, John R., Lagos, Claudia, Kuehn, Kyler, Gordon, Yjan, Barat, Dilyar, Bian, Fuyan, Wolf, Christian, Cowley, Michael J., White, Marc, Achitouv, Ixandra, Bilicki, Maciej, Bland-Hawthorn, Joss, Bolejko, Krzysztof, Brown, Michael J. I., Brown, Rebecca, Bryant, Julia, Croom, Scott, Davis, Tamara M., Driver, Simon P., Filipovic, Miroslav D., Hinton, Samuel R., Johnston-Hollitt, Melanie, Jones, D. Heath, Koribalski, Baerbel, Kleiner, Dane, Lawrence, Jon, Lorente, Nuria, Mould, Jeremy, Owers, Matt S., Pimbblet, Kevin, Tinney, C. G., Tothill, Nicholas F. H., and Watson, Fred

Subjects

Astrophysics - Astrophysics of Galaxies, Astrophysics - Cosmology and Nongalactic Astrophysics

Abstract

Taipan is a multi-object spectroscopic galaxy survey starting in 2017 that will cover 2pi steradians over the southern sky, and obtain optical spectra for about two million galaxies out to z<0.4. Taipan will use the newly-refurbished 1.2m UK Schmidt Telescope at Siding Spring Observatory with the new TAIPAN instrument, which includes an innovative 'Starbugs' positioning system capable of rapidly and simultaneously deploying up to 150 spectroscopic fibres (and up to 300 with a proposed upgrade) over the 6-deg diameter focal plane, and a purpose-built spectrograph operating from 370 to 870nm with resolving power R>2000. The main scientific goals of Taipan are: (i) to measure the distance scale of the Universe (primarily governed by the local expansion rate, H_0) to 1% precision, and the structure growth rate of structure to 5%; (ii) to make the most extensive map yet constructed of the mass distribution and motions in the local Universe, using peculiar velocities based on improved Fundamental Plane distances, which will enable sensitive tests of gravitational physics; and (iii) to deliver a legacy sample of low-redshift galaxies as a unique laboratory for studying galaxy evolution as a function of mass and environment. The final survey, which will be completed within 5 years, will consist of a complete magnitude-limited sample (i<17) of about 1.2x10^6 galaxies, supplemented by an extension to higher redshifts and fainter magnitudes (i<18.1) of a luminous red galaxy sample of about 0.8x10^6 galaxies. Observations and data processing will be carried out remotely and in a fully-automated way, using a purpose-built automated 'virtual observer' software and an automated data reduction pipeline. The Taipan survey is deliberately designed to maximise its legacy value, by complementing and enhancing current and planned surveys of the southern sky at wavelengths from the optical to the radio., Comment: Published in PASA; 29 pages, 17 figures, 2 tables

Published

2017

5. SHαDE: survey description and mass–kinematics scaling relations for dwarf galaxies

Author

Barat, Dilyar, primary, D’Eugenio, Francesco, additional, Colless, Matthew, additional, Sweet, Sarah M, additional, Groves, Brent, additional, and Cortese, Luca, additional

Published

2020

6. The SAMI Galaxy Survey: mass–kinematics scaling relations

Author

Barat, Dilyar, primary, D’Eugenio, Francesco, primary, Colless, Matthew, primary, Brough, Sarah, primary, Catinella, Barbara, primary, Cortese, Luca, primary, Croom, Scott M, primary, Medling, Anne M, primary, Oh, Sree, primary, van de Sande, Jesse, primary, Sweet, Sarah M, primary, Yi, Sukyoung K, primary, Bland-Hawthorn, Joss, primary, Bryant, Julia, primary, Goodwin, Michael, primary, Groves, Brent, primary, Lawrence, Jon, primary, Owers, Matt S, primary, Richards, Samuel N, primary, and Scott, Nicholas, primary

Published

2019

7. Key dynamical results from the SAMI Galaxy Survey.

Author

van de Sande, Jesse, Bland-Hawthorn, Joss, Barat, Dilyar, Brough, Sarah, Bryant, Julia J., Croom, Scott M., Cortese, Luca, Valluri, Monica, and Sellwood, J. A.

Abstract

We present an overview of recent key results from the SAMI Galaxy Survey on the build-up of mass and angular momentum in galaxies across morphology and environment. The SAMI Galaxy survey is a multi-object integral field spectroscopic survey and provides a wealth of spatially-resolved, two-dimensional stellar and gas measurements for galaxies of all morphological types, with high-precision due the stable spectral resolution of the AAOmega spectrograph. The sample size of ~3000 galaxies allows for dividing the sample in bins of stellar mass, environment, and star-formation or morphology, whilst maintaining a statistical significant number of galaxies in each bin. By combining imaging, spatially resolved dynamics, and stellar population measurements, our result demonstrate the power of utilising integral field spectroscopy on a large sample of galaxies to further our understanding of physical processes involved in the build-up of stellar mass and angular momentum in galaxies. [ABSTRACT FROM AUTHOR]

Published

2020

8. The SAMI Galaxy Survey: Data Release Two with absorption-line physics value-added products

Author

Scott, Nicholas, primary, van de Sande, Jesse, additional, Croom, Scott M, additional, Groves, Brent, additional, Owers, Matt S, additional, Poetrodjojo, Henry, additional, D’Eugenio, Francesco, additional, Medling, Anne M, additional, Barat, Dilyar, additional, Barone, Tania M, additional, Bland-Hawthorn, Joss, additional, Brough, Sarah, additional, Bryant, Julia, additional, Cortese, Luca, additional, Foster, Caroline, additional, Green, Andrew W, additional, Oh, Sree, additional, Colless, Matthew, additional, Drinkwater, Michael J, additional, Driver, Simon P, additional, Goodwin, Michael, additional, Gunawardhana, Madusha L P, additional, Federrath, Christoph, additional, Harischandra, Lloyd, additional, Jin, Yifei, additional, Lawrence, J S, additional, Lorente, Nuria P, additional, Mannering, Elizabeth, additional, O’Toole, Simon, additional, Richards, Samuel N, additional, Sanchez, Sebastian F, additional, Schaefer, Adam L, additional, Sealey, Katrina, additional, Sharp, Rob, additional, Sweet, Sarah M, additional, Taranu, Dan S, additional, and Varidel, Mathew, additional

Published

2018

9. The Taipan Galaxy Survey: Scientific Goals and Observing Strategy

Author

da Cunha, Elisabete, primary, Hopkins, Andrew M., additional, Colless, Matthew, additional, Taylor, Edward N., additional, Blake, Chris, additional, Howlett, Cullan, additional, Magoulas, Christina, additional, Lucey, John R., additional, Lagos, Claudia, additional, Kuehn, Kyler, additional, Gordon, Yjan, additional, Barat, Dilyar, additional, Bian, Fuyan, additional, Wolf, Christian, additional, Cowley, Michael J., additional, White, Marc, additional, Achitouv, Ixandra, additional, Bilicki, Maciej, additional, Bland-Hawthorn, Joss, additional, Bolejko, Krzysztof, additional, Brown, Michael J. I., additional, Brown, Rebecca, additional, Bryant, Julia, additional, Croom, Scott, additional, Davis, Tamara M., additional, Driver, Simon P., additional, Filipovic, Miroslav D., additional, Hinton, Samuel R., additional, Johnston-Hollitt, Melanie, additional, Jones, D. Heath, additional, Koribalski, Bärbel, additional, Kleiner, Dane, additional, Lawrence, Jon, additional, Lorente, Nuria, additional, Mould, Jeremy, additional, Owers, Matt S., additional, Pimbblet, Kevin, additional, Tinney, C. G., additional, Tothill, Nicholas F. H., additional, and Watson, Fred, additional

Published

2017

10. SAMI Galaxy Survey: mass–kinematics scaling relations.

Author

Barat, Dilyar, D'Eugenio, Francesco, Colless, Matthew, Brough, Sarah, Catinella, Barbara, Cortese, Luca, Croom, Scott M, Medling, Anne M, Oh, Sree, van de Sande, Jesse, Sweet, Sarah M, Yi, Sukyoung K, Bland-Hawthorn, Joss, Bryant, Julia, Goodwin, Michael, Groves, Brent, Lawrence, Jon, Owers, Matt S, Richards, Samuel N, and Scott, Nicholas

Subjects

*STELLAR rotation, *GALAXIES, *STELLAR mass

Abstract

We use data from the Sydney-AAO Multi-object Integral-field spectroscopy (SAMI) Galaxy Survey to study the dynamical scaling relation between galaxy stellar mass M ∗ and the general kinematic parameter |$S_K = \sqrt{K V_{\rm rot}^2 + \sigma ^2}$| that combines rotation velocity V rot and velocity dispersion σ. We show that the log  M ∗ – log  SK relation: (1) is linear above limits set by properties of the samples and observations; (2) has slightly different slope when derived from stellar or gas kinematic measurements; (3) applies to both early-type and late-type galaxies and has smaller scatter than either the Tully–Fisher relation (log  M ∗ − log  V rot) for late types or the Faber–Jackson relation (log  M ∗ − log σ) for early types; and (4) has scatter that is only weakly sensitive to the value of K , with minimum scatter for K in the range 0.4 and 0.7. We compare SK to the aperture second moment (the 'aperture velocity dispersion') measured from the integrated spectrum within a 3-arcsecond radius aperture (⁠|$\sigma _{3^{\prime \prime }}$|⁠). We find that while SK and |$\sigma _{3^{\prime \prime }}$| are in general tightly correlated, the log  M ∗ − log  SK relation has less scatter than the |$\log M_* - \log \sigma _{3^{\prime \prime }}$| relation. [ABSTRACT FROM AUTHOR]

Published

2019