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Dwarf Galaxy Rotation Curves and the Core Problem of Dark Matter Halos

Frank C. van den Bosch, Rob A. Swaters

TL;DR

The paper tests whether the rotation curves of 20 late-type dwarf galaxies are compatible with LCDM halos once beam-smearing and adiabatic contraction are included. It uses a three-component mass model (gas disk, thick stellar disk, and a dark halo with a flexible inner slope) and accounts for observational PSF effects by convolving model predictions before comparing to data. The results show the data cannot decisively exclude constant-density cores but are fully consistent with LCDM halos and also accommodate alternative DM models with shallower inner cusps, indicating that rotation curves alone yield only weak cosmological or DM-type constraints. The work underscores the importance of high-resolution data and careful modeling of baryonic and observational effects in testing dark-matter paradigms for dwarf galaxies.

Abstract

The standard cold dark matter (CDM) model has recently been challenged by the claim that dwarf galaxies have dark matter halos with constant density cores. Consequently, numerous alternative dark matter candidates have recently been proposed. In this paper, we scrutinize the observational evidence for the incongruity between dwarf galaxies and the CDM model. To this end, we analyze the rotation curves of 20 late-type dwarf galaxies studied by Swaters (1999). Taking the effects of beam-smearing and adiabatic contraction into account, we fit mass models to these rotation curves with dark matter halos with different cusp slopes, ranging from constant density cores to r^{-2} cusps. Uncertainties in the stellar mass-to-light ratio and the limited spatial sampling of the halo's density distribution hamper a unique mass decomposition. Consequently, the rotation curves in our sample cannot be used to discriminate between dark halos with constant density cores and r^{-1} cusps. We show that the dwarf galaxies analyzed here are consistent with cold dark matter halos in a LCDM cosmology, and that there is thus no need to abandon the idea that dark matter is cold and collisionless. However, the data is also consistent with any alternative dark matter model that produces dark matter halos with central cusps less steep than r^{-1.5}. In fact, we argue that based on existing rotation curves alone at best weak limits can be obtained on cosmological parameters and/or the nature of the dark matter.

Dwarf Galaxy Rotation Curves and the Core Problem of Dark Matter Halos

TL;DR

The paper tests whether the rotation curves of 20 late-type dwarf galaxies are compatible with LCDM halos once beam-smearing and adiabatic contraction are included. It uses a three-component mass model (gas disk, thick stellar disk, and a dark halo with a flexible inner slope) and accounts for observational PSF effects by convolving model predictions before comparing to data. The results show the data cannot decisively exclude constant-density cores but are fully consistent with LCDM halos and also accommodate alternative DM models with shallower inner cusps, indicating that rotation curves alone yield only weak cosmological or DM-type constraints. The work underscores the importance of high-resolution data and careful modeling of baryonic and observational effects in testing dark-matter paradigms for dwarf galaxies.

Abstract

The standard cold dark matter (CDM) model has recently been challenged by the claim that dwarf galaxies have dark matter halos with constant density cores. Consequently, numerous alternative dark matter candidates have recently been proposed. In this paper, we scrutinize the observational evidence for the incongruity between dwarf galaxies and the CDM model. To this end, we analyze the rotation curves of 20 late-type dwarf galaxies studied by Swaters (1999). Taking the effects of beam-smearing and adiabatic contraction into account, we fit mass models to these rotation curves with dark matter halos with different cusp slopes, ranging from constant density cores to r^{-2} cusps. Uncertainties in the stellar mass-to-light ratio and the limited spatial sampling of the halo's density distribution hamper a unique mass decomposition. Consequently, the rotation curves in our sample cannot be used to discriminate between dark halos with constant density cores and r^{-1} cusps. We show that the dwarf galaxies analyzed here are consistent with cold dark matter halos in a LCDM cosmology, and that there is thus no need to abandon the idea that dark matter is cold and collisionless. However, the data is also consistent with any alternative dark matter model that produces dark matter halos with central cusps less steep than r^{-1.5}. In fact, we argue that based on existing rotation curves alone at best weak limits can be obtained on cosmological parameters and/or the nature of the dark matter.

Paper Structure

This paper contains 8 sections, 10 equations, 1 figure, 1 table.

Table of Contents

  1. Introduction
  2. The data
  3. Rotation curve fitting
  4. Mass components
  5. Beam smearing
  6. Fitting procedure
  7. Uncertainties on the rotation velocities
  8. Degeneracies in the mass modelling

Figures (1)

  • Figure :