Hiding Planets Behind a Big Friend: Mutual Inclinations of Multi-Planet Systems with External Companions

The {\it Kepler} mission has detected thousands of planetary systems with 1-7 transiting planets packed within 0.7~au from their host stars. There is an apparent excess of single-transit planet systems that cannot be explained by transit geometries alone, when a single planetary mutual inclination d...

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Bibliographic Details
Published in:arXiv.org 2016-11
Main Authors: Lai, Dong, Bonan Pu
Format: Article
Language:English
Subjects:
Extrasolar planets
Inclination
Planet detection
Planetary systems
Planets
Online Access:Get full text
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Summary:The {\it Kepler} mission has detected thousands of planetary systems with 1-7 transiting planets packed within 0.7~au from their host stars. There is an apparent excess of single-transit planet systems that cannot be explained by transit geometries alone, when a single planetary mutual inclination dispersion is assumed. This suggests that the observed compact planetary systems have at least two different architectures. We present a scenario where the "Kepler dichotomy" may be explained by the action of an external giant planet or stellar companion misaligned with the inner multi-planet system. The external companion excites mutual inclinations of the inner planets, causing such systems to appear as "Kepler singles" in transit surveys. We derive approximate analytic expressions (in various limiting regimes), calibrated with numerical calculations, for the mutual inclination excitations for various planetary systems and perturber properties (mass \(m_p\), semi-major axis \(a_p\) and inclination \(\theta_p\)). In general, the excited mutual inclination increases with \(m_p/a_p^3\) and \(\theta_p\), although secular resonances may lead to large mutual inclinations even for small \(\theta_p\). We discuss the implications of our results for understanding the dynamical history of transiting planet systems with known external perturbers.
ISSN:2331-8422
DOI:10.48550/arxiv.1606.08855