English

Radiating Bondi Flows I: Dimensionless Framework and Constant Opacity Solutions

Earth and Planetary Astrophysics 2026-03-24 v1 Solar and Stellar Astrophysics

Abstract

In this paper, we extend the foundational work of Bondi (1952) to include the effects of radiative feedback in gas-pressure-dominated environments. We construct steady-state spherically symmetric accretion solutions including radiative heating and cooling. Under the simplifying assumption of a constant opacity, the solutions are controlled by four dimensionless parameters: the adiabatic index γ\gamma, optical depth through the Bondi radius τB\tau_B, dimensionless luminosity at infinity L~\tilde{L}_\infty, and a characteristic dimensionless cooling time β\beta. We present numerical solutions across the dimensionless parameter space (τB,L~,β)[103,103](\tau_B, \tilde{L}_\infty, \beta)\in [10^{-3}, 10^3]. Contrary to radiation-pressure-dominated environments, radiative feedback primarily operates to suppress accretion -- particularly at high τB\tau_B, L~\tilde{L}_\infty, and/or β\beta. We also present analytic descriptions confirming the suppressive nature of this feedback and give the scalings for the accretion rate M˙L~5/4\dot{M}\sim \tilde{L}_\infty^{-5/4} at large L~\tilde{L}_\infty, M˙τB10/11β5/11\dot{M}\sim \tau_B^{-10/11}\beta^{-5/11} at large τB\tau_B, and M˙(L~τB)5/8\dot{M}\sim (\tilde{L}_\infty\tau_B)^{-5/8} for large L~τB\tilde{L}_\infty\tau_B. We discuss the potential role of convection in these steady-state solutions, and the particular relevance to problems of planet formation where radiative heating is significant, but the system remains in the gas-pressure-dominated regime.

Keywords

Cite

@article{arxiv.2603.20373,
  title  = {Radiating Bondi Flows I: Dimensionless Framework and Constant Opacity Solutions},
  author = {Avery Bailey and Andrew Youdin and Kaitlin Kratter},
  journal= {arXiv preprint arXiv:2603.20373},
  year   = {2026}
}

Comments

First paper in a series. See accompanying Paper II for applications to planet formation. Submitted to MNRAS; 22 pages, 11 figures

R2 v1 2026-07-01T11:30:30.299Z