2009A&A...494...95M

Query : 2009A&A...494...95M

2009A&A...494...95M - Astronomy and Astrophysics, volume 494, 95-108 (2009/1-4)

The evolution of the galactic metallicity gradient from high-resolution spectroscopy of open clusters.

MAGRINI L., SESTITO P., RANDICH S. and GALLI D.

Abstract (from CDS):

Open clusters offer a unique possibility to study the time evolution of the radial metallicity gradients of several elements in our Galaxy, because they span large intervals in age and Galactocentric distance, and both quantities can be more accurately derived than for field stars. We re-address the issue of the Galactic metallicity gradient and its time evolution by comparing the empirical gradients traced by a sample of 45 open clusters with a chemical evolution model of the Galaxy. At variance with previous similar studies, we have collected from the literature only abundances derived from high-resolution spectra. The clusters have Galactocentric distances 7≲RGC≲22kpc and ages from ∼30Myr to 11Gyr. We also consider the α-elements Si, Ca, Ti, and the iron-peak elements Cr and Ni. Cepheids trace instead the present-day Fe gradient in the inner parts of the disk. The data for iron-peak and α-elements indicate a steep metallicity gradient for RGC≲12kpc and a plateau at larger radii. The time evolution of the metallicity distribution is characterized by a uniform increase of the metallicity at all radii, preserving the shape of the gradient, with marginal evidence for a flattening of the gradient with time in the radial range 7-12kpc. Our model is able to reproduce the main features of the metallicity gradient and its evolution with an infall law exponentially decreasing with radius and with a collapse time scale of the order of 8 Gyr at the solar radius. This results in a rapid collapse in the inner regions, i.e. RGC≲12kpc (that we associate with an early phase of disk formation from the collapse of the halo) and in a slow inflow of material per unit area in the outer regions at a constant rate with time (that we associate with accretion from the intergalactic medium). An additional uniform inflow per unit disk area would help to better reproduce the metallicity plateau at large Galactocentric radii, but it is difficult to reconcile with the present-day radial behaviour of the star formation rate. Our results favour a scenario where the Galactic disk is formed inside-out by the rapid collapse of the halo and by a subsequent continuous accretion of intergalactic gas

Abstract Copyright:

Journal keyword(s): Galaxy: disk - Galaxy: abundances - Galaxy: evolution - open clusters and associations: general

Simbad objects: 47

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Number of rows : 47
N Identifier Otype ICRS (J2000)
RA 		ICRS (J2000)
DEC 		Mag U Mag B Mag V Mag R Mag I Sp type #ref
1850 - 2024 		#notes
1 Cl Blanco 1 OpC 00 03 24.7 -29 57 29           ~ 326 0
2 NGC 188 OpC 00 47 11.5 +85 14 38           ~ 922 0
3 M 33 GiG 01 33 50.8965749232 +30 39 36.630403128 6.17 6.27 5.72     ~ 5845 1
4 NGC 1039 OpC 02 42 07.4 +42 43 19           ~ 431 0
5 Cl Berkeley 66 OpC 03 04 07.2 +58 43 52           ~ 68 0
6 Cl Melotte 22 OpC 03 46 24.2 +24 06 50           ~ 3436 0
7 Cl Melotte 25 OpC 04 29 47.3 +16 56 53           ~ 3081 0
8 Cl Berkeley 17 OpC 05 20 31.2 +30 34 26           ~ 174 0
9 Cl Berkeley 20 OpC 05 32 36.5 +00 11 06           ~ 120 0
10 NGC 2112 OpC 05 53 48.5 +00 24 11     9.1     ~ 91 0
11 Cl Berkeley 22 OpC 05 58 28.3 +07 45 47           ~ 84 0
12 NGC 2141 OpC 06 02 56.2 +10 27 04           ~ 145 0
13 Cl Berkeley 73 OpC 06 22 04.8 -06 19 16           ~ 54 0
14 NGC 2243 OpC 06 29 34.8 -31 16 55   10.12 9.4     ~ 269 0
15 Cl Berkeley 25 OpC 06 41 16.1 -16 29 13           ~ 60 0
16 Cl Ruprecht 4 OpC 06 49 00 -10 31.4           ~ 44 0
17 Cl Berkeley 75 OpC 06 49 00.5 -23 59 56           ~ 61 0
18 Cl Berkeley 29 OpC 06 53 04.2 +16 55 39   14.3       ~ 174 0
19 Cl Berkeley 31 OpC 06 57 37.4 +08 17 06           ~ 128 0
20 Cl Berkeley 33 OpC 06 57 49.4 -13 13 37           ~ 86 0
21 Cl Berkeley 32 OpC 06 58 07.2 +06 25 59           ~ 145 0
22 NGC 2324 OpC 07 04 07.9 +01 02 46   8.83 8.4     ~ 159 0
23 NGC 2360 OpC 07 17 46.3 -15 37 52           ~ 194 0
24 NAME Saurer A Cluster OpC 07 20.9 +01 48           ~ 64 0
25 Cl Melotte 66 OpC 07 26 17.5 -47 41 06   8.73       ~ 196 0
26 Cl Melotte 71 OpC 07 37 31.9 -12 03 54   7.44 7.1     ~ 130 0
27 NGC 2477 OpC 07 52 11.0 -38 32 13   6.64 5.8     ~ 290 0
28 NGC 2506 OpC 08 00 02.4 -10 46 23   8.28 7.6     ~ 276 0
29 NGC 2632 OpC 08 40 13.0 +19 37 16           ~ 1566 0
30 IC 2391 OpC 08 41 10.1 -52 59 28           ~ 822 0
31 NGC 2660 OpC 08 42 40.1 -47 12 04   9.05 8.8     ~ 152 0
32 NGC 2682 OpC 08 51 23.0 +11 48 50           ~ 2342 0
33 IC 2602 OpC 10 42 27.1 -64 25 34           ~ 675 0
34 NGC 3680 OpC 11 25 34.1 -43 14 24   8.40 7.6     ~ 319 0
35 NGC 3960 OpC 11 50 34.6 -55 40 44   9.07 8.3     ~ 140 0
36 Cl Collinder 261 OpC 12 38 04.6 -68 22 37     10.7     ~ 192 0
37 NGC 6134 OpC 16 27 48.7 -49 09 40   7.89 7.2     ~ 152 0
38 NGC 6253 OpC 16 59 06.7 -52 42 43     10.2     ~ 186 0
39 IC 4651 OpC 17 24 50.9 -49 55 01           ~ 350 0
40 NAME Galactic Center reg 17 45 39.60213 -29 00 22.0000           ~ 14448 0
41 IC 4665 OpC 17 46 13.0 +05 36 54           ~ 372 0
42 NGC 6475 OpC 17 53 47.3 -34 50 28           ~ 384 0
43 NGC 6705 OpC 18 51 03.8 -06 16 19   6.32 5.8     ~ 411 0
44 NGC 6791 OpC 19 20 53.0 +37 46 41   10.52 9.5     ~ 1040 0
45 NGC 6819 OpC 19 41 18.5 +40 11 24   8.21 7.3     ~ 635 0
46 NGC 7142 OpC 21 45 09.6 +65 46 55   10.36 9.3     ~ 143 0
47 NGC 7789 OpC 23 57 20.2 +56 43 34   7.68 6.7     ~ 528 0

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