Low-Eccentricity Migration of Ultra-Short Period Planets in Multi-Planet Systems

Recent studies suggest that ultra-short period planets (USPs), Earth-sized planets with sub-day periods, constitute a statistically distinct sub-sample of {\it Kepler} planets: USPs have smaller radii (\(1-1.4R_\oplus\)) and larger mutual inclinations with neighboring planets than nominal {\it Keple...

Full description

Saved in:
Bibliographic Details
Published in:arXiv.org 2019-04
Main Authors: Bonan Pu, Lai, Dong
Format: Article
Language:English
Subjects:
Angular momentum
Eccentric orbits
Extrasolar planets
Inclination
Migration
Orbit decay
Orbital resonances (celestial mechanics)
Planet formation
Planetary systems
Postal & delivery services
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Recent studies suggest that ultra-short period planets (USPs), Earth-sized planets with sub-day periods, constitute a statistically distinct sub-sample of {\it Kepler} planets: USPs have smaller radii (\(1-1.4R_\oplus\)) and larger mutual inclinations with neighboring planets than nominal {\it Kepler} planets, and their period distribution is steeper than longer-period planets. We study a "low-eccentricity" migration scenario for the formation of USPs, in which a low-mass planet with initial period of a few days maintains a small but finite eccentricity due to secular forcings from exterior companion planets, and experiences orbital decay due to tidal dissipation. USP formation in this scenario requires that the initial multi-planet system have modest eccentricities (\(\gtrsim 0.1\)) or angular momentum deficit. During the orbital decay of the inner-most planet, the system can encounter several apsidal and nodal precession resonances that significantly enhance eccentricity excitation and increase the mutual inclination between the inner planets. We develop an approximate method based on eccentricity and inclination eigenmodes to efficiently evolve a large number of multi-planet systems over Gyr timescales in the presence of rapid (as short as \(\sim 100\)~years) secular planet-planet interactions and other short-range forces. Through a population synthesis calculation, we demonstrate that the "low-\(e\) migration" mechanism can naturally produce USPs from the large population of {\it Kepler} multis under a variety of conditions, with little fine tuning of parameters. This mechanism favors smaller inner planets with more massive and eccentric companion planets, and the resulting USPs have properties that are consistent with observations.
ISSN:2331-8422
DOI:10.48550/arxiv.1901.08258