Accurate Inner Stellar Density Slopes from Projected Surface Densities in Galaxies

Sánchez Almeida, Jorge
Referencia bibliográfica

The Astrophysical Journal

Fecha de publicación:
6
2026
Número de autores
1
Número de autores del IAC
1
Número de citas
0
Número de citas referidas
0
Descripción
The inner slope of the three-dimensional stellar density in dwarf galaxies ( ρ'[0] ) is a sensitive probe of possible departures from the collisionless cold dark matter (CDM) paradigm, since cored stellar distributions ( ρ'[0]=0 ) cannot easily reside within the cuspy potentials CDM predicts for low-mass systems. Photometry alone offers an observationally inexpensive way to constrain ρ'(0) , making this approach particularly attractive for the faint galaxies most relevant to dark matter studies. Inferring volume densities, however, requires deprojecting the observed stellar surface density, Σ(R), a procedure that is notoriously ambiguous in the presence of noise. To avoid explicit deprojection, we derive an expression (Equation (9)) to obtain ρ'(0) directly from the radial derivatives of Σ(R), assuming spherical symmetry and smooth finite density profiles. All projected profiles are shown to have the same central functional form, independent of the underlying volume density (Equation (20)). As a result, the derivatives of Σ(R) can be extrapolated to the center using constraints from larger radii, which in turn yields ρ'(0) . As an illustration, we apply the method to six ultrafaint dwarf galaxies, finding that all of them have a surface density with the same shape, from which the presence of stellar cores is inferred ( ρ'[0]≃0 ). The technique also has the ability to diagnose ρ'[0]>0 , corresponding to galaxies with a central stellar mass deficit potentially linked to black-hole scouring, modified Newtonian dynamics , or deviations from CDM.