On Eccentric Protoplanetary Disks I -- How Eccentric are Planet-Perturbed Disks?

Abstract

Protoplanetary disks can become eccentric when planets open deep gaps within, but how eccentric are they? We answer this question by analyzing two-dimensional hydrodynamical simulations of planet-disk interaction. The steady state eccentricity of the outer disk (outside of the planet's orbit) is described as a balance between eccentricity excitation by the 1:3 eccentric Lindblad resonance and eccentricity damping by gas pressure. This eccentricity scales with q(hprp)(-1)(rgaprp)(a-b2-2), where q is the planet-to-star mass ratio, hprp is the disk aspect ratio, rgaprp is the radial position of the outer gap edge divided by the planet's position, and a and b are the negative exponents in the disk's surface density and temperature power law profiles, respectively. We derive a semi-analytic eccentricity profile that agrees with numerical simulations to within 30%. Our result is a first step to quantitatively interpret observations of eccentric protoplanetary disks, such as MWC 758, HD 142527, IRS 48, and CI Tau.