Extremely Large Telescope

SDSS-IV MaStar: Theoretical atmospheric parameters for the MaNGA stellar library

Monthly Notices of the Royal Astronomical Society Oxford University Press (OUP) (2021)

Authors:

Lewis Hill, Daniel Thomas, Claudia Maraston, Renbin Yan, Justus Neumann, Andrew Lundgren, Daniel Lazarz, Yan-Ping Chen, Michele Cappellari, Jon A Holtzman, Julie Imig, Katia Cunha, Guy Stringfellow, Dmitry Bizyaev, David R Law, Keivan G Stassun, Niv Drory, Michael Merrifield, Timothy C Beers

Abstract:

Abstract We calculate the fundamental stellar parameters effective temperature, surface gravity and iron abundance - Teff, log g, [Fe/H] - for the final release of the Mapping Nearby Galaxies at APO (MaNGA) Stellar Library (MaStar), containing 59,266 per-visit-spectra for 24,290 unique stars at intermediate resolution (R ∼ 1800) and high S/N (median = 96). We fit theoretical spectra from model atmospheres by both MARCS and BOSZ-ATLAS9 to the observed MaStar spectra, using the full spectral fitting code pPXF. We further employ a Bayesian approach, using a Markov Chain Monte Carlo (MCMC) technique to map the parameter space and obtain uncertainties. Originally in this paper, we cross match MaStar observations with Gaia photometry, which enable us to set reliable priors and identify outliers according to stellar evolution. In parallel to the parameter determination, we calculate corresponding stellar population models to test the reliability of the parameters for each stellar evolutionary phase. We further assess our procedure by determining parameters for standard stars such as the Sun and Vega and by comparing our parameters with those determined in the literature from high-resolution spectroscopy (APOGEE and SEGUE) and from lower-resolution matching template (LAMOST). The comparisons, considering the different methodologies and S/N of the literature surveys, are favourable in all cases. Our final parameter catalogue for MaStar cover the following ranges: 2592 ≤ Teff ≤ 32983 K; −0.7 ≤ log g ≤5.4 dex; −2.9 ≤ [Fe/H] ≤1.0 dex and will be available with the last SDSS-IV Data Release, in December 2021.

Cross-checking SMBH mass estimates in NGC 6958 – I. Stellar dynamics from adaptive optics-assisted MUSE observations

Monthly Notices of the Royal Astronomical Society Oxford University Press 509:4 (2021) 5416-5436

Authors:

Sabine Thater, Davor Krajnović, Peter M Weilbacher, Dieu D Nguyen, Martin Bureau, Michele Cappellari, Timothy A Davis, Satoru Iguchi, Richard McDermid, Kyoko Onishi, Marc Sarzi, Glenn van de Ven

Abstract:

Supermassive black hole masses (MBH) can dynamically be estimated with various methods and using different kinematic tracers. Different methods have only been cross-checked for a small number of galaxies and often show discrepancies. To understand these discrepancies, detailed cross-comparisons of additional galaxies are needed. We present the first part of our cross-comparison between stellar- and gas-based MBH estimates in the nearby fast-rotating early-type galaxy NGC 6958. The measurements presented here are based on ground-layer adaptive optics-assisted Multi-Unit Spectroscopic Explorer (MUSE) science verification data at around 0′′.6 spatial resolution. The spatial resolution is a key ingredient for the measurement and we provide a Gaussian parametrisation of the adaptive optics-assisted point spread function (PSF) for various wavelengths. From the MUSE data, we extracted the stellar kinematics and constructed dynamical models. Using an axisymmetric Schwarzschild technique, we measured an MBH of (3.6+2.7−2.4)×108M⊙ at 3σ significance taking kinematical and dynamical systematics (e.g. radially-varying mass-to-light ratio) into account. We also added a dark halo, but our data does not allow to constrain the dark matter fraction. Adding dark matter with an abundance matching prior results in a 25 per cent more massive black hole. Jeans anisotropic models return MBH of (4.6+2.5−2.7)×108M⊙ and (8.6+0.8−0.8)×108M⊙ at 3σ confidence for spherical and cylindrical alignment of the velocity ellipsoid, respectively. In a follow-up study, we will compare the stellar-based MBH with those from cold and warm gas tracers, which will provide additional constraints for the MBH for NGC 6958, and insights into assumptions that lead to potential systematic uncertainty.

SDSS-IV MaStar: Theoretical Atmospheric Parameters for the MaNGA Stellar Library

(2021)

Authors:

Lewis Hill, Daniel Thomas, Claudia Maraston, Renbin Yan, Justus Neumann, Andrew Lundgren, Daniel Lazarz, Yan-Ping Chen, Michele Cappellari, Jon A Holtzman, Julie Imig, Katia Cunha, Guy Stringfellow, Dmitry Bizyaev, David R Law, Keivan G Stassun, Niv Drory, Michael Merrifield, Timothy C Beers

Cross-checking SMBH mass estimates in NGC 6958 -- I: Stellar dynamics from adaptive optics-assisted MUSE observations

(2021)

Authors:

Sabine Thater, Davor Krajnović, Peter M Weilbacher, Dieu D Nguyen, Martin Bureau, Michele Cappellari, Timothy A Davis, Satoru Iguchi, Richard McDermid, Kyoko Onishi, Marc Sarzi, Glenn van de Ven

The GRAVITY young stellar object survey

Astronomy & Astrophysics EDP Sciences 655 (2021) a73

Authors:

K Perraut, L Labadie, J Bouvier, F Ménard, L Klarmann, C Dougados, M Benisty, J-P Berger, Y-I Bouarour, W Brandner, A Caratti O Garatti, P Caselli, PT de Zeeuw, R Garcia-Lopez, T Henning, J Sanchez-Bermudez, A Sousa, E van Dishoeck, E Alécian, A Amorim, Y Clénet, R Davies, A Drescher, G Duvert, A Eckart, F Eisenhauer, NM Förster-Schreiber, P Garcia, E Gendron, R Genzel, S Gillessen, R Grellmann, G Heißel, S Hippler, M Horrobin, Z Hubert, L Jocou, P Kervella, S Lacour, V Lapeyrère, J-B Le Bouquin, P Léna, D Lutz, T Ott, T Paumard, G Perrin, S Scheithauer, J Shangguan, T Shimizu, J Stadler, O Straub, C Straubmeier, E Sturm, L Tacconi, F Vincent, S von Fellenberg, F Widmann