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A&A 375, 366374 (2001) DOI: 10.1051/0004-6361:20010814
c ESO 2001

Astronomy & Astrophysics

The stellar content of the Hamburg/ESO survey
I I. A large, homogeneously-selected sample of high latitude carb on stars
N. Christlieb1 , P. J. Green2 , L. Wisotzki3 , and D. Reimers
1

1

2

3

Hamburger Sternwarte, UniversitЁ Hamburg, Go jenbergsweg 112, 21029 Hamburg, Germany at e-mail: dreimers@hs.uni-hamburg.de Harvard-Smithsonian Center for Astrophysics, 60 Garden Street, Cambridge, MA 02140, USA e-mail: pgreen@cfa.harvard.edu Institut fur Physik, UniversitЁ Potsdam, Am Neuen Palais 10, 14469 Potsdam, Germany Ё at e-mail: lutz@astro.physik.uni-potsdam.de

Received 26 April 2001 / Accepted 5 June 2001

Abstract. We present a sample of 403 faint high latitude carbon (FHLC) stars selected from the digitized ob jective prism plates of the Hamburg/ESO Survey (HES). Because of the 15 ° spectral resolution and high signal-toA noise ratio of the HES prism spectra, our automated procedure based on the detection of C2 and CN molecular bands permits high-confidence identification of carbon stars without the need for follow-up spectroscopy. From a set of 329 plates (87 % of the survey), covering 6 400 deg2 to a magnitude limit of V 16.5, we analyze the selection efficiency and effective surface area of the HES FHLC survey to date. The surface density of FHLC stars that we detect (0.072 ± 0.005 deg-2 ) is 24 times higher than that of previous ob jective prism and CCD surveys at high galactic latitude, even though those surveys claimed a limiting magnitude up to 1.5 magnitudes fainter. This attests to the highest selection sensitivity yet achieved for these types of stars. Key words. stars: carbon surveys Galaxy: halo

1. Intro duction
Models of the chemical and dynamical properties of the Galactic spheroid (the "halo") are still rather weakly constrained. In the grand scheme, did a monolithic protogalaxy undergo rapid collapse and enrichment (Eggen et al. 1962), or did many smaller dwarf galaxies merge together (Searle & Zinn 1978)? Both processes probably contribute, since there is solid recent evidence of ongoing mergers (Ibata et al. 1994; Ma jewski et al. 2000). Stars and gas that are tidally stripped from accreting dwarf galaxies remain aligned with the orbit of the satellite for timescales comparable to the age of the Galaxy. Thus, a number of tidal streams exist today whose phase-space signature can
Send offprint requests to : N. Christlieb, e-mail: nchristlieb@hs.uni-hamburg.de Based on observations collected at the European Southern Observatory, Chile (Proposal IDs 145.B-0009 and 63.L-0148). Table A.1 is only available in electronic form at the CDS via anonymous ftp to cdsarc.u-strasbg.fr (130.79.125.5) or via http://cdsweb.u-strasbg.fr/cgi-bin/qcat?J/A+A/375/366

constrain the stripping and merging events that contribute to the present-day galactic halo (Johnston et al. 1999). An important goal of astronomy in this century is to measure and model the potential of the Milky Way using halo stars as tracers. To simultaneously disentangle the remnants of disrupted satellites requires full knowledge of the angular positions, proper motions, radial velocities, and distances of a large number of such stars. But first, a large sample of distant halo stars must be amassed. Intrinsically bright stars visible to large galactocentric distances (10100 kpc) provide the best opportunity. Because they are readily recognizable from their strong C2 and CN absorption bands, and because they were thought without exception to be giants, faint C stars have been sought as excellent tracers of the outer halo. Faint high galactic latitude carbon (FHLC) stars have been sought in prior ob jective prism surveys (e.g., Sanduleak & Pesch 1988; MacAlpine & Lewis 1978) and in the CCD survey of Green et al. (1994). Ob jectiveprism photography with wide-field Schmidt telescopes has yielded low-dispersion spectra for thousands of objects over substantial portions of the sky, but not a large

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number of carbon stars. Fewer than 1% of the 6000 stars in Stephenson's (1989) catalogue are the faint, high-latitude carbon (FHLC) stars (V > 13, |b| > 40 ) most useful as dynamical probes of the outer halo. The two most prolific sources of published FHLC stars, the Case low-dispersion survey (CLS; Sanduleak & Pesch 1988) and the University of Michigan Cerro Tololo survey (UM; MacAlpine & Williams 1981) appear to probe to about V = 16 and have provided about 30 FHLC stars. Emission-line ob jects, not FHLC stars, were the primary goal of these photographic surveys, and known FHLC stars were not examined to help predefine selection criteria or estimate completeness. The surface density of FHLC stars from ob jective-prism surveys is low, about one per 50 deg2 to V 16. At high galactic latitudes, mostly warm carbon stars are found CH stars, and possibly some R stars. However, color selection of very red stars at high latitude also reveals a small number (one per 200 deg2 to R 16) of classical intermediate, age AGB carbon (AGBC) stars (Totten & Irwin 1998). Margon et al. (2000) recently reported the discovery of more than 30 new FHLC stars in the commissioning data of the Sloan Digitized Sky Survey (SDSS), which may eventually provide the ma jority of known FHLC stars. In this paper, we describe our use of the Hamburg/ESO survey (HES; Wisotzki et al. 1996; Reimers & Wisotzki 1997; Wisotzki et al. 2000) to greatly augment the number of known FHLC stars. The HES is an ob jective-prism survey designed to select bright (12.5 BJ 17.5) quasars in the southern extragalactic sky ( < +2.5 ; |b| 30 ). It is based on IIIa-J plates taken with the 1 m ESO Schmidt telescope and its 4 prism, yielding a wavelength range of 3200 ° < < 5200 ° and a seeing-limited spectral A A resolution of typically 15 ° at H . This resolution makes A possible the identification of carbon stars with high confidence without follow-up slit spectroscopy, based on their strong C2 and CN molecular bands (cf. Fig. 1). Since carbon can reach the surface of an isolated star only in late evolutionary stages, it has long been assumed that all carbon (C) stars are giants. Due to their high luminosity (MR -3.5), it is possible to detect the red AGBC stars at large distances: Brewer et al. (1996) have identified C stars even in the local group galaxy M 31. The more typical FHLC stars such as CH giants, with 0 < MV < -2.5, can be detected to 60 kpc in sensitive photographic surveys. However, the long-held assumption that all C stars are giants has charged. Trigonometric parallax measurements for the carbon star G7761 (Dahn et al. 1977) showed that this star lies close to the main sequence (MV +10). For years, the dwarf carbon (dC) star phenomenon was assumed to be extremely rare until many new dCs were discovered in the early 1990s (Green et al. 1991; Green et al. 1992; Warren et al. 1993; Heber et al. 1993; Liebert et al. 1994). Discovery of so many dCs, and the remarkable similarity of their spectra to those of C giants means that care must be taken to distinguish dwarfs from giants in FHLC star samples intended for distant halo studies (Green et al. 1992). We are there-

Fig. 1. HES ob jective prism spectrum of the R-type carbon star CGCS 2954 (Stephenson 1989), illustrating the positions of continuum (black) and band (grey) bandpasses defining the C2 (high boxes) and CN (flat boxes) line indices used for selection in the HES. The abscissa is density above diffuse sky background in arbitrary units. Note that wavelength is decreasing ° towards the right. The sharp drop of the spectra at 5400 A is due to the IIIa-J emulsion sensitivity cutoff.

fore undertaking a two-part investigation. In the current paper, we describe our automated selection of C stars in the HES, and we present a large, uniformly selected, and flux-limited sample of FHLC stars. We complement this sample in an upcoming work with recent epoch astrometry, to measure proper motions for as many ob jects as possible, and thereby separate the dCs from C giants. We note that carbon-enhanced, metal-poor stars may be among the FHLC stars presented here. It was recognized by several authors that the fraction of such stars among metal-poor stars rises with decreasing metallicity, reaching 25% for stars with [Fe/H] < -3.0, and that carbon overabundances are as high as [C/Fe] = +2.0dex (e.g., Norris et al. 1997; Rossi et al. 1999). 12 C/13 C isotope measurements of a larger sample of such stars would help to identify the carbon production site(s) at work.

2. Carb on star selection
The full HES database consists of 10 million extracted, wavelength calibrated spectra. The input catalog for extraction of ob jective-prism spectra is generated by using the Digitized Sky Survey I (DSS I). An astrometric transformation between DSS I plates and HES plates yields, for each ob ject in the input catalog, the location of its spectrum on the relevant HES plate, and provides a wavelength calibration zero point (Wisotzki et al. 2000). Carbon stars can be identified in the HES database by their strong C2 and CN bands. We select carbon star candidates when the mean signal-to-noise ratio (S/N ) in the relevant wavelength range is >5 per pixel and

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Table 1. Wavelengths of passbands used for computation of C band indices in the HES. "cont" = continuum; "flux" = feature passband. Use for band index C2 5165 cont flux cont cont flux cont cont flux flux cont Fig. 2. Selection of carbon stars in the I (C2 5165) versus I (C2 4737) plane. Band strengths are measured by line indices. Dots: all spectra on a randomly chosen HES plate; boxes: test sample of known FHLC stars present on HES plates (see Table 4); dashed box selection region. Spectra in which only one high C2 band index value was measured suffer either from an overlapping spectrum, or from a plate artifact. The selection in the I (CN 4216) versus I (CN 3883) plane is done analogously. The two test sample ob jects outside the selection box are CGCS 525 and CGCS 3180. They are selected by CN band indices (see Table 4). C2 4737 CN 4216 CN 3883

Passband 51905240 ° A 50605150 ° A 48004970 ° A ° 46204730 A 44604560 ° A ° 42104270 A 41304180 ° A 38303890 ° A ° 36103740 A

Table 2. Carbon star selection criteria. The maximum allowed band index values correspond to an integrated density of zero in the feature passbands. That is, larger band indices can only be due to artifacts, e.g. scratches, causing photographic densities (above skybackground) < 0. Stars are selected if both of their C2 indices or both of their CN indices fall into the indicated ranges. Feature C2 5165 C2 4737 CN 4216 CN 3883 ° Index range [A] [10,91] [15,114] [2,56] [13,55]

both of the C2 bands 5165, 4737, or both of the CN bands 4216, 3883 are stronger than a selection threshold. Band strengths are measured by means of line indices ratios of the mean photographic densities in the carbon molecular absorption features and the continuum bandpasses shown in Fig. 1, and listed in Table 1. The use of pairs of indices prevents confusion with plate artifacts, e.g., scratches. It is very unlikely that two such artifacts are present at the positions of two molecular bands. Selection boxes in the I (C2 5165) versus I (C2 4737) and I (CN 4216) versus I (CN 3883) planes were chosen well-separated from the dense locus of "normal" stars (see Fig. 2). The selection criteria are listed in Table 2. Carbon stars can be distinguished reliably from other late type stars, e.g. M or S stars, even if only weak C bands are present in their spectra (cf. Fig. 3). Other potential sample contaminators are white dwarfs of type DQ, which show carbon molecular bands. However, since the latter usually have a much bluer continuum (see Fig. B.1), they can easily be recognized by visual inspection of the spectra, and by their U - B color. McCook & Sion (1999) list 49 DQs, of which 30 have an available U - B measurement. The average U - B of those is -0.58, i.e., 1.5 mag

Fig. 3. Comparison of HES spectra of the C star HE 1524-0210, exhibiting a weak C band only, with two M stars. The abscissa is the same as in Fig. 1.

away from the average U - B of the HES C star sample. Our U -B colors are measured directly from the HES spectra with a mean accuracy of U -B = 0.09 mag (Christlieb et al. 2001 hereafter Paper I). The average U - B of HES C stars is 0.9, more than 90% have U - B > 0.5, and there is no C star of U - B < 0 in the HES sample. While four (i.e., 13%) of the 30 DQs with U - B in McCook & Sion (1999) have U - B > 0.0, the pressure-broadened

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Fig. 4. V magnitude and B - V distribution of the HES FHLC sample. B - V was derived from HES spectra with the procedures described in Paper I.

features of DQs are easily distinguished by visual inspection of the carbon bands (see Fig. B.1). With a rough estimate of their surface density, we can quantify an upper limit for the contamination of the HES C star sample by "red" (U - B > 0.0) DQs. First of all, we have to take into account that the ratio of northern hemisphere to southern hemisphere DQs is unbalanced in McCook & Sion (1999), as much as is the total catalog. This is because the southern hemisphere so far has been surveyed less extensively for white dwarfs. Assuming that the northern hemisphere sample of DQs is complete, we derive a surface density of 9 DQs brighter than V = 16.5 in 20 000 deg2 , i.e. 4.5 в 10-4 deg-2 . Hence, the surface density of U - B > 0.0 DQs is 5.9 в 10-5 deg-2 , and we expect 0.44 DQs to be present on all 329 plates currently used for the exploitation of the stellar content of the HES. Therefore, even if we assume that the sample of DQs known so far is incomplete by a factor of 2, we statistically expect less than 1 DQ to be present in the HES C star sample. On the 329 HES plates (effective area 6 400 deg2 ) we found 403 FHLCs. 90 of them were selected by C2 band indices only, 171 by CN band indices only, and 144 by C2 and CN indices. The V and B - V distributions are displayed in Fig. 4. The faintest ob jects have V 16.5, and the most distant ob jects reach 35 kpc (cf. Fig. 5), assuming they are all giants with MV = -1 mag.

Fig. 5. Distance distribution of the 393 HES FHLCs with available V magnitudes, assuming that they are all giants with MV = -1 mag.

3.1. Selection efficiency
An important criterion for the evaluation of the quality of a selection algorithm is the selection efficiency, i.e. the fraction of desired stars in the raw candidate sample. Table 3 summarizes the results. Our selection is very efficient. The low fraction of artifacts demonstrates that the usage of pairs of C2 bands and CN bands indeed very reliably excludes artifacts from selection. However, a considerable number of overlapping spectra (overlaps) are selected. Overlaps are detected by an automatic overlap detection algorithm in the HES, using the direct plate data of the DSS I. It appears that our carbon star selection technique is very sensitive in finding the small number of overlaps not detected by the automatic algorithm.

3. Testing the automated selection
We tested the automated selection extensively and by various methods. In Sect. 3.1 we investigate the selection efficiency. In Sect. 3.2 we derive plate-by-plate selection probabilities for halo dCs on HES plates by simulations. The results of tests with "real" ob jects are given in Sect. 3.3.

3.2. Decrease of selection probability for halo dCs
In the HES, some care must be taken when ob jects with large proper motion are selected. This is because the input catalog for extraction of ob jective prism spectra is

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Table 3. Selection efficiency for C stars in the HES. UNID = probable C stars with weak C bands, OVL = overlapping spectra, ART = artifacts, NOIS = very noisy spectra, SAT = saturated spectra. The raw candidate reduction factor is the factor by which the selection algorithm reduces the total set of 3 437 630 overlap-free HES spectra with S/N > 5 present on 329 HES plates. Raw candidate reduction factor C stars UNID OVL ART N OI S SAT 1/2900 31.6% 7.0% 29.2% 8.7% 3.8% 15.6%

generated by using the DSS I. The dispersion direction of the HES spectra is along declination. Therefore, large proper motions and/or large epoch differences between HES and DSS I plates (13.5 years on average) may result in an offset of the wavelength calibration zero point, leading to smaller C band values, and/or non-detection of ob jects in the HES, if µ tHES-DSS I 4 , i.e., > 3 pixels. Offsets of µ tHES-DSS I < 4 can be recovered by the spectrum extraction algorithm. Note however that proper motions of a typical halo ob ject ( = = 0 km s-1 ; 200 km s-1 ) result in 2в larger offsets along declination than in R.A., since the galactic plane is tilted by 62.6 with respect to the equatorial coordinate system. In order to estimate how many dCs are expected to be missed in our survey due to the epoch difference problem, we carried out a simulation study in which the plateby-plate selection function for halo dCs was determined. The simulation is similar to that described in Green et al. (1992). We employ a sample of simulated dCs with halo kinematics, as given by Norris (1986). For the solar neighborhood, he gives vrot = 37 ± 10 km s-1 = -187 km s u = 131 ± 6km s-1 v = 106 ± 6km s-1 w = 85 ± 6km s-1 .
-1

of the star after the time tHES-DSS I , the epoch difference between DSS I and HES plate, and derive proper motions µ , µ from the position differences. We then select the subsample of the 8600 stars with µ tHES-DSS I < 4 . As a test sample for an investigation of the dependence of the selection probability on µ t, we used a sample of 78 C stars from 44 HES plates without significant p.m., as measured in an follow-up campaign carried out in April at ESO, using the Wide Field Imager attached to the MPG/ESO 2.2 m telescope (Christlieb et al., in preparation). The stars were shifted in one pixel (= 1 . 35) steps through the range -700 µm < x < +700 µm, corresponding to -47 . 25 < µ t < 47 . 25. At each shift step, the selection algorithms were applied. By applying the selection probability (a function of µ t) to the subsample of the 8600 stars with µ tHES-DSS I < 4 , we determine the fraction of stars which would be detected in the HES and selected by our selection algorithm. On the 329 stellar HES plates, 21.4% of the simulated halo dCs are detected and selected. Green et al. (1992) found that 13% of their C stars are dwarfs. Applying this estimate to our sample, and taking into account that we find only 20% of the dCs detectable on the HES plates, we estimate that 1015 out of our 403 FHLCs are dCs. However, since our sample is biased to low-p.m., it is likely that not all of these can be proven to be dCs by their transverse velocity. Based on our simulations we estimate that additional 40 dCs would be detectable on the HES plates, but are currently missed due to the epoch difference problem. This incompleteness will be addressed in a later paper focusing on dC stars in the HES.

3.3. Tests with known C stars
We also compiled a test sample of known dwarf and giant C stars present on HES plates (see Table 4). We took all three dCs in the southern hemisphere listed by Deutsch (1994), i.e. LHS 1075, G7761, and KA 2. The (possible) dCs of Warren et al. (1993), having BJ > 20, unfortunately are by far too faint to be detectable on HES plates. Cross-identification with the C star lists of Slettebak et al. (1969), Stephenson (1989), Bothun et al. (1991), and Totten & Irwin (1998), yielded 21 stars. Another 6 spectra were produced from slit spectra with the procedures described in Paper I. In our test, al l 21 stars not known as dwarfs were selected either by their strong C2 bands, or their CN bands. The simulated spectra were also al l selected. Of the three dCs, one (KA 2) was selected, and the other two (G7761, LHS 1075) not. From these results we conclude that our sample of giant C stars and dwarfs with low p.m. (e.g. dCs belonging to the disk population) is highly complete. From the small number of dCs in our test sample we are not able to draw any definitive conclusions, but our results suggest that only a minor fraction of the halo dCs

,

(1)

and he determined the velocity ellipsoid to be (2) (3) (4)

In each simulation we constructed 100 random velocity vectors (u, v , w), with components following Gaussian distributions according to the above parameters. These velocity vectors were each applied to stars located at the center of the plate under investigation, and converted to proper motions assuming distances d. These were computed from the apparent V magnitude distribution of a sample of 86 C stars without significant p.m. (see Fig. 4), and assuming MV = +10 for dwarf carbon stars. This yields 86 · 100 = 8600 simulated stars. We compute the position

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Table 4. Test sample of dwarf and giant C stars present on HES plates. Sources: BEM91 = Bothun et al. (1991), D94 = Deutsch (1994), S89 = Stephenson (1989), SKB69 = Slettebak et al. (1969), TI98 = Totten & Irwin (1998). Stars marked with TI98 have been recently reported by Totten et al. (2000) to have no significant p.m. Therefore, we list them with (µ t, µ t) = (0, 0). KA 2 was not selected by CN bands, using its real spectrum, but it was selected in the course of our simulations. This is because the S/N at the position of the CN bands is too low in the former spectrum, and effectively infinite in the simulated spectrum. Selected by Name CGCS 39 S KB 2 BEM91 23 CGCS 177 S KB 5 0207-0211 BEM91 08 CGCS 525 CGCS 935 0915-0327 1019-1136 CGCS 2954 CGCS 3180 CGCS 3274 1254-1130 1339-0700 1442-0058 CGCS 5435 CGCS 5549 2213-0017 2225-1401 CLS 50 CLS 31 CLS 54 KA 2 B1509-0902 UM 515 LHS 1075 KA 2 G77-61 HE 0023-1935 HE 1116-1628 HE 0330+0148 16.1 16.6 15.0 1.4 1.3 1.4 HE Name HE 0017+0055 HE 0039-2635 HE 0100-1619 HE 0106-2837 HE 0111-1346 HE 0207-0211 HE 0228-0256 HE 0330-2815 HE 0521-3425 HE 0915-0327 HE 1019-1136 HE 1104-0957 HE 1207-3156 HE 1238-0836 HE 1254-1130 HE 1339-0700 HE 1442-0058 HE 2144-1832 HE 2200-1652 HE 2213-0017 HE 2225-1401 BJ (sat.) 13.1 15.9 13.8 13.3 15.5 16.2 13.8 13.0 14.5 15.2 (sat.) 12.8 (sat.) 16.1 15.0 17.8 12.6 12.3 16.4 16.5 2.2 1.7 2.2 1.4 0.9 2.4 2.9 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 -0 . 24 -0 . 21 1. 9 0.0 0.0 0.0 0.0 0.0 0.0 0.0 0.0 -10 . 0 0 . 24 -7 . 5 0.0 0.0 0.0 0.0 0.0 0.0 1.2 1.1 1.5 2.1 1.4 2.2 2.0 1.5 1.3 2.3 1.8 0.0 0.0 0.0 0.0 0.0 0.0 B-V µ t µ t C2 1 1 1 1 1 1 1 0 1 1 1 1 0 1 1 1 1 0 1 1 1 1 1 1 1 1 1 0 1 0 CN 1 1 0 0 1 0 0 1 1 0 0 1 1 1 0 0 0 1 1 0 0 0 1 1 1 1 0 0 0 0 All 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 0 1 0 Source S89 SKB69 BEM91 S89 SKB69 TI98 BEM91 S89 S89 TI98 TI98 S89 S89 S89 TI98 TI98 TI98 S89 S89 TI98 TI98 Simul. Simul. Simul. Simul. Simul. Simul. D94 D94 D94

are detected in the HES. This is consistent with 20% of the simulated halo dCs being found (see Sect. 3.2).

4. The surface density of C stars
In an effective area of 6400 deg2 (329 of 380 the HES plates; for a description of how the effective area is es-

timated see Wisotzki et al. 2000), we have isolated a total of 403 C stars. A straightforward estimate of the surface density of FHLC stars we detect with the HES is hence obtained from the ratio of these two numbers, yielding 0.063 deg-2 . However, one has to take into account that the effective area accessible on average for each ob ject depends on its brightness, since the HES limiting magnitude varies from plate to plate. For example, the effective area

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for an ob ject as faint as B = 17.0 is only 73% of the overall survey area, mainly because only 254 of the contributing plates reach this magnitude (see Fig. 2 in Wisotzki et al. 2000). An additional brightness dependence is caused by the fact that faint ob jects are more easily affected by overlapping spectra than bright ob jects. We therefore determine the FHLC surface density as follows:
403

to include proper-motion corrected input catalogs for the extraction of HES spectra, to find al l dCs, and other objects that can have large proper motions, like halo white dwarfs.

surface density =
i=1

1 , effarea(BJ )i

(5)

where effarea(BJ ) was determined as described in Wisotzki et al. (2000). We obtain a FHLC surface density of 0.072 ± 0.005 deg-2 on the 329 HES plates we used.

Acknow ledgements. We thank D. Koester for providing model spectra of DQs, and C. Fechner for technical support in preparing this article. This work was partly supported by Deutsche Forschungsgemeinschaft under grant Re 353/40. P. J. G. acknowledges support through NASA Contract NAS8-39073 (ASC).

App endix A: The HES FHLC sample 5. Discussion and conclusions
In an effective area of 6400 deg2 we have isolated a total of 403 C stars. Our efforts have thus already increased the number of known FHLC stars by a factor of nearly five. We find almost quadruple the surface density of carbon stars compared to the surveys summarized by Green et al. (1994). Since those previous surveys claimed limiting magnitudes about 1.5 mag fainter than the HES, this highlights the greatly enhanced selection sensitivity of FHLC stars in the HES, which is more sensitive to a variety of C2 or CN molecular absorption band strengths. Automated selection techniques may be superior to visible inspection of ob jective-prism spectra with binocular microscopes, as done e.g. in the survey of Sanduleak & Pesch (1988). Photometric surveys for C stars have generally selected red ob jects only, which preferentially selects mostly the much less common high latitude AGB stars. Margon et al. (2000) report a FHLC star surface density of "at least" 0.04 deg-2 in the SDSS. This is still almost a factor of 2 below our value, and again, the SDSS is much deeper than the HES (r < 19.5). Due to an average epoch difference of 13.5 years between DSS I and HES plates, we expect to detect and select only 20% of the halo dCs that we could detect and select if direct plates had been taken simultaneously with the HES plates. Our simulations indicate that 1015 out of the 403 FHLCs published in this paper are dCs. Note, however, that this number is uncertain, because the kinematics of halo dCs is not precisely known. We estimate that an additional 40 dCs are detectable on the HES plates, but are currently missed due to the epoch difference problem. We are extending the current sample In Table A.1 we list the sample of 403 HES FHLC stars described in this paper. The table is made available only electronically. It contains the following columns: hename ra2000 dec2000 field plate q ob jtyp BJ V B-V U -B C2idx1 C2idx2 CNidx1 CNidx3 selC2 selCN HE designation RA at equinox 2000.0, derived from DSS I Declination at equinox 2000.0, derived from DSS I ESO-SERC field number HES plate number Plate quarter Ob ject type (stars/bright/ext) BJ magnitude V magnitude B - V magnitude, derived from HES spectra U - B magnitude, derived from HES spectra A Band index of C2 5165 ° Band index of C2 4737 ° A Band index of CN 4216 ° A Band index of CN 3883 ° A C2 band index selection flag CN band index selection flag

BJ magnitudes are accurate to better than ±0.2 mag, including zero point errors (Wisotzki et al. 2000). V magnitudes were derived by the procedures described in Paper I. The ob ject types "stars", "bright" and "ext" refer to point sources, sources above a saturation threshold, and sources detected as extended in DSS I images, respectively. We do not list V , B - V and U - B for saturated ob jects, because our color calibrations are not valid for them.

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App endix B: HES example sp ectra of C stars

Fig. B.1. HES spectra of a representative sample of seven C stars, displaying a variety of C2 and CN band strengths. The spectra of KA 2 and CLS 31 were converted to ob jective-prism spectra from slit spectra with the procedures described in Paper I. For comparison, the spectrum of a DQ white dwarf with Teff = 6 500 K and C/He = 10-6 is shown in the lower right panel. That star has U - B = -0.6.

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N. Christlieb et al.: Carbon stars from the Hamburg/ESO survey MacAlpine, G. M., & Williams, G. A. 1981, ApJS, 45, 113 Ma jewski, S. R., Ostheimer, J. C., Kunkel, W. E., et al. 2000, AJ, 120, 2550 Margon, B., Anderson, S. F., Williams, B. F., et al. 2000, in AAS Meeting, 197, 1309 McCook, G. P., & Sion, E. M. 1999, ApJS, 121, 1 Norris, J. 1986, ApJS, 61, 667 Norris, J. E., Ryan, S. G., & Beers, T. C. 1997, ApJ, 488, 350 Reimers, D., & Wisotzki, L. 1997, The Messenger, 88, 14 Rossi, S., Beers, T. C., & Sneden, C. 1999, in ASP Conf. Ser., 165, The Third Stromlo Symposium: The Galactic Halo, ed. B. Gibson, T. Axelrod, & M. Putman, 264 Sanduleak, N., & Pesch, P. 1988, ApJS, 66, 387 Searle, L., & Zinn, R. 1978, ApJ, 225, 357 Slettebak, A., Keenan, P. C., & Brundage, R. K. 1969, AJ, 74, 373 Stephenson, C. B. 1989, Publ. W. & S. Obs, 3 Totten, E. J., & Irwin, M. J. 1998, MNRAS, 294, 1 Totten, E. J., Irwin, M. J., & Whitelock, P. A. 2000, MNRAS, 314, 630 Warren, S. J., Irwin, M. J., Evans, D. W., et al. 1993, MNRAS, 261, 185 Wisotzki, L., KЁ ler, T., Groote, D., et al. 1996, A&AS, 115, oh 227 Wisotzki, L., Christlieb, N., Bade, N., et al. 2000, A&A, 358, 77

References
Bothun, G., Elias, J. H., MacAlpine, G., et al. 1991, AJ, 101, 2220 Brewer, J. P., Richer, H. B., & Crabtree, D. R. 1996, AJ, 112, 491 Christlieb, N., Wisotzki, L., Reimers, D., et al. 2001, A&A, 366, 898 (Paper I) Dahn, C. C., Liebert, J., Kron, R. G., et al. 1977, ApJ, 216, 757 Deutsch, E. W. 1994, PASP, 106, 1134 Eggen, O. J., Lynden-Bell, D., & Sandage, A. R. 1962, ApJ, 136, 748 Green, P. J., Margon, B., & MacConnell, D. J. 1991, ApJ, 380, L31 Green, P. J., Margon, B., & Anderson, S. F. 1992, ApJ, 400, 659 Green, P. J., Margon, B., Anderson, S. F., et al. 1994, ApJ, 434, 319 Heber, U., Bade, N., Jordan, S., et al. 1993, A&A, 267, L31 Ibata, R. A., Gilmore, G., & Irwin, M. J. 1994, Nature, 370, 194 Johnston, K. V., Zhao, H., Spergel, D. N., et al. 1999, ApJ, 512, L109 Liebert, J., Schmidt, G. D., Lesser, M., et al. 1994, ApJ, 421, 733 MacAlpine, G. M., & Lewis, D. W. 1978, ApJS, 36, 587