The core of the problem: Physical limits of the core-S\'ersic model

TL;DR

This paper investigates the physical limits of the core-Sérsic model in describing stellar cores in galaxies, revealing that certain parameter combinations produce non-physical density profiles and are thus invalid.

Contribution

It identifies critical transition parameters that constrain the physically admissible parameter space of the core-Sérsic model, challenging some common assumptions.

Findings

Sharp transitions with large alpha produce non-monotonic densities.

A critical alpha value depends on core slope and Sersic index.

Some widely used parameter choices are physically ruled out.

Abstract

The core-S\'ersic model is the standard tool for describing partially depleted stellar cores in massive early-type galaxies, yet its physical admissibility has rarely been examined. Using numerical deprojections, we show that many formally allowed parameter combinations cannot represent realistic stellar systems: sharp transitions between the inner power-law core and the outer S\'ersic profile (large $\alpha$) always generate non-monotonic intrinsic density profiles. We identify, for each set of structural parameters $(\gamma, m, R_{\text{e}}/R_{\text{b}})$, a critical transition parameter, $\alpha_{\text{crit}}$, above which monotonicity is violated. This threshold systematically depends on the core slope and S\'ersic index, implying that a fraction of the commonly used parameter space, including the widely adopted sharp-transition limit $\alpha\rightarrow\infty$, is physically ruled out. These constraints have important consequences for measuring core sizes and mass deficits in massive ellipticals, for constructing dynamical models, and for comparing observations with simulations of supermassive black hole binary evolution.