Early-type galaxy distances from the Fundamental Plane and surface brightness fluctuations

We compare two of the most popular methods for deriving distances to early-type galaxies: the Fundamental Plane (FP) and surface brightness fluctuations (SBF). Distances for 170 galaxies are compared. A third set of distances is provided by predictions derived from the density field of the IRAS reds...

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Veröffentlicht in:Monthly notices of the Royal Astronomical Society 2002-02, Vol.330 (2), p.443-457
Hauptverfasser: Blakeslee, John P., Lucey, John R., Tonry, John L., Hudson, Michael J., Narayanan, Vijay K., Barris, Brian J.
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Sprache:eng
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Zusammenfassung:We compare two of the most popular methods for deriving distances to early-type galaxies: the Fundamental Plane (FP) and surface brightness fluctuations (SBF). Distances for 170 galaxies are compared. A third set of distances is provided by predictions derived from the density field of the IRAS redshift survey. Overall there is good agreement between the different distance indicators. We investigate systematic trends in the residuals of the three sets of distance comparisons. First, we find that several nearby, low-luminosity, mainly S0 galaxies have systematically low FP distances. Because these galaxies also have Mg2 indices among the lowest in the sample, we conclude that they deviate from the FP partly because of recent star formation and consequently low mass-to-light ratios; differences in their internal velocity structures may also play a role. Secondly, we find some evidence that the ground-based I-band SBF survey distances (Tonry et al. 2001) begin to show a bias near the survey limit at cz≳3500 km s−1, which is expected for this sort of distance-limited survey, but had not previously been demonstrated. Although SBF and FP distances are affected in opposite senses by errors in the Galactic extinction estimates, we find no evidence for biases in the distances due to Galactic extinction. The tie between the Cepheid-calibrated SBF distances (Mpc) and the far-field calibrated FP distances (km s−1) yields a Hubble constant H0=68±3 km s−1 Mpc−1, while the comparison between SBF and the IRAS-reconstructed distances yields H0=74±2 km s−1 Mpc−1 (independent errors only). Thus there is a marginal inconsistency in the direct and IRAS-reconstructed ties to the Hubble flow (this can be seen independently of the SBF distances). Possible explanations include systematic errors in the redshift survey completeness estimates or in the FP aperture corrections, but at this point the best estimate of H0 may come from a simple average of the above two estimates. After revising the SBF distances downward by 2.8 per cent to be in agreement with the final set of Key Project Cepheid distances (Freedman et al.), we conclude that H0=73±4±11 km s−1 Mpc−1 from early-type galaxies, where the second error bar represents the total systematic uncertainty in the distance zero-point. We also discuss the ‘fluctuation star count’N¯≡m¯− mtot, recently introduced by Tonry et al. (2001) as a less demanding alternative to (V−I) for calibrating SBF distances. The N¯-calibrated SBF method is
ISSN:0035-8711
1365-2966
DOI:10.1046/j.1365-8711.2002.05080.x