TY - JOUR
T1 - Chemical evolution of the inner 2 degrees of the Milky Way bulge: [α/Fe] trends and metallicity gradients
AU - Ryde, Nils
AU - Schultheis, Mathias
AU - Grieco, V.
AU - Matteucci, Francesca
AU - Rich, R. M.
AU - Uttenthaler, Stefan
N1 - Publisher Copyright:
© 2016. The American Astronomical Society. All rights reserved.
PY - 2016
Y1 - 2016
N2 - The structure, formation, and evolution of the Milky Way bulge is a matter of debate. Important diagnostics for discriminating between models of bulge formation and evolution include α-abundance trends with metallicity, and spatial abundance and metallicity gradients. Due to the severe optical extinction in the inner Bulge region, only a few detailed investigations of this region have been performed. Here we aim at investigating the inner 2 degrees of the Bulge (projected galactocentric distance of approximately 300 pc), rarely investigated before, by observing the [α/Fe] element trends versus metallicity, and by trying to derive the metallicity gradient in the b < 2° region. [α/Fe] and metallicities have been determined by spectral synthesis of 2 μm spectra of 28 M-giants in the Bulge, lying along the southern minor axis at (l, b) = (0, 0), (0, -1°), and (0, -2°). These were observed with the CRIRES spectrometer at the Very Large Telescope, (VLT) at high spectral resolution. Low-resolution K-band spectra, observed with the ISAAC spectrometer at the VLT, are used to determine the effective temperature of the stars. We present the first connection between the Galactic center (GC) and the Bulge using similar stars, high spectral resolution, and analysis techniques. The [α/Fe] trends in all our three fields show a large similarity among each other and with trends further out in the Bulge. All point to a rapid star formation episode in the Bulge. We find that there is a lack of an [α/Fe] gradient in the Bulge all the way into the center, suggesting a homogeneous Bulge when it comes to the enrichment process and star formation history. We find a large range of metallicities from -1.2 < [Fe/H] < +0.3, with a lower dispersion in the GC: -0.2 < [Fe/H] < +0.3. The derived metallicities of the stars in the three fields get, in the mean, progressively higher the closer to the Galactic plane they lie. We could interpret this as a continuation of the metallicity gradient established further out in the Bulge, but due to the low number of stars and possible selection effects, more data of the same sort as presented here is necessary to conclude on the inner metallicity gradient from our data alone. Our results firmly argue for the center being in the context of the Bulge rather than very distinct.
AB - The structure, formation, and evolution of the Milky Way bulge is a matter of debate. Important diagnostics for discriminating between models of bulge formation and evolution include α-abundance trends with metallicity, and spatial abundance and metallicity gradients. Due to the severe optical extinction in the inner Bulge region, only a few detailed investigations of this region have been performed. Here we aim at investigating the inner 2 degrees of the Bulge (projected galactocentric distance of approximately 300 pc), rarely investigated before, by observing the [α/Fe] element trends versus metallicity, and by trying to derive the metallicity gradient in the b < 2° region. [α/Fe] and metallicities have been determined by spectral synthesis of 2 μm spectra of 28 M-giants in the Bulge, lying along the southern minor axis at (l, b) = (0, 0), (0, -1°), and (0, -2°). These were observed with the CRIRES spectrometer at the Very Large Telescope, (VLT) at high spectral resolution. Low-resolution K-band spectra, observed with the ISAAC spectrometer at the VLT, are used to determine the effective temperature of the stars. We present the first connection between the Galactic center (GC) and the Bulge using similar stars, high spectral resolution, and analysis techniques. The [α/Fe] trends in all our three fields show a large similarity among each other and with trends further out in the Bulge. All point to a rapid star formation episode in the Bulge. We find that there is a lack of an [α/Fe] gradient in the Bulge all the way into the center, suggesting a homogeneous Bulge when it comes to the enrichment process and star formation history. We find a large range of metallicities from -1.2 < [Fe/H] < +0.3, with a lower dispersion in the GC: -0.2 < [Fe/H] < +0.3. The derived metallicities of the stars in the three fields get, in the mean, progressively higher the closer to the Galactic plane they lie. We could interpret this as a continuation of the metallicity gradient established further out in the Bulge, but due to the low number of stars and possible selection effects, more data of the same sort as presented here is necessary to conclude on the inner metallicity gradient from our data alone. Our results firmly argue for the center being in the context of the Bulge rather than very distinct.
KW - 1ST DETAILED ABUNDANCES
KW - COOL STARS
KW - ELEMENT ABUNDANCES
KW - FLAMES-GIRAFFE SPECTRA
KW - GALACTIC BULGE
KW - Galaxy: bulge
KW - Galaxy: stellar content
KW - Galaxy: structure
KW - LATE-TYPE STARS
KW - M-GIANTS
KW - NEAR-IR SPECTRA
KW - RESOLUTION INFRARED-SPECTROSCOPY
KW - STELLAR POPULATIONS
KW - infrared: stars
KW - stars: abundances
KW - stars: fundamental parameters
UR - http://www.scopus.com/inward/record.url?scp=84954478220&partnerID=8YFLogxK
U2 - 10.3847/0004-6256/151/1/1
DO - 10.3847/0004-6256/151/1/1
M3 - Article
SN - 0004-6256
VL - 151
JO - The Astronomical Journal
JF - The Astronomical Journal
IS - 1
M1 - 1
ER -