The Calibration of the WISE W1 and W2 Tully-Fisher Relation

Abstract

In order to explore local large-scale structures and velocity fields, accurate galaxy distance measures are needed. We now extend the well-tested recipe for calibrating the correlation between galaxy rotation rates and luminosities -- capable of providing such distance measures -- to the all-sky, space-based imaging data from the Wide-field Infrared Survey Explorer (WISE) W1 (3.4μm) and W2 (4.6μm) filters. We find a linewidth to absolute magnitude correlation (known as the Tully-Fisher Relation, TFR) of Mb,i,k,aW1 = -20.35 - 9.56 ( Wimx - 2.5) (0.54 magnitudes rms) and Mb,i,k,aW2 = -19.76 - 9.74 ( Wimx - 2.5) (0.56 magnitudes rms) from 310 galaxies in 13 clusters. We update the I-band TFR using a sample 9% larger than in Tully & Courtois (2012). We derive Mb,i,kI = -21.34 - 8.95 ( Wimx - 2.5) (0.46 magnitudes rms). The WISE TFRs show evidence of curvature. Quadratic fits give Mb,i,k,aW1 = -20.48 - 8.36 ( Wimx - 2.5) + 3.60 ( Wimx - 2.5)2 (0.52 magnitudes rms) and Mb,i,k,aW2 = -19.91 - 8.40 ( Wimx - 2.5) + 4.32 ( Wimx - 2.5)2 (0.55 magnitudes rms). We apply an I-band -- WISE color correction to lower the scatter and derive MCW1 = -20.22 - 9.12 ( Wimx - 2.5) and MCW2 = -19.63 - 9.11 ( Wimx - 2.5) (both 0.46 magnitudes rms). Using our three independent TFRs (W1 curved, W2 curved and I-band), we calibrate the UNION2 supernova Type Ia sample distance scale and derive H0 = 74.4 1.4(stat) \ 2.4(sys) kms-1 Mpc-1 with 4% total error.