Fast-rotating galaxies do not depart from the MOND mass-asymptotic-speed relation

Abstract

Ogle et al. have fallaciously argued recently that fast-rotating disc galaxies break with the predictions of MOND: the 6 fastest rotators of the 23 galaxies in their sample appear to have higher rotational speeds than is consistent with the MOND relation between the baryonic mass of a galaxy, M, and its `rotational speed', V. They interpret this departure as a break in the observed M-V relation from a logarithmic slope near the MOND-predicted 4, to a shallow slope of ≈ 0. However, Ogle et al. use the MAXIMAL rotational speed of the galaxies, Vmax, not the ASYMPTOTIC one, V∞, which appears in the MOND prediction, V∞4=MGa0. Plotting their M vs. Vmax pairs on an M vs. V∞ plot from Lelli et al. (2016), they arrive erroneously at the above tension with MOND. The Hα rotation curves used by Ogle et al. are far too short reaching to probe the asymptotic regime, and determine V∞. However, it is well documented for fast rotators with observed, extended, HI rotation curves, that they can have Vmax considerably larger than the MOND-relevant V∞ [Noordermeer and Verheijen (NV) (2007) and others]. E.g., the fastest rotator in the NV sample has Vmax≈ 490 ~km/s, but V∞≈ 250 ~km/s. NV also show that in a (MOND-irrelevant) M-Vmax plot the high-speed galaxies fall off the power-law line defined by the lower-speed ones, creating a break in the M vs. V relation, in just the way claimed by Ogle et al. But, when plotting the MOND-relevant M vs. V∞ all galaxies fall near the same power-law relation, without a break.