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STABILITY OF SATELLITES IN CLOSELY PACKED PLANETARY SYSTEMS

Abstract

We perform numerical integrations of four-body (star, planet, planet, satellite) systems to investigate the stability of satellites in planetary systems with tightly packed inner planets (STIPs). We find that the majority of closely spaced stable two-planet systems can stably support satellites across a range of parameter-space which is only slightly decreased compared to that seen for the single-planet case. In particular, circular prograde satellites remain stable out to ~0.4 R[subscript H] (where R[subscript H] is the Hill radius) as opposed to 0.5 R[subscript H] in the single-planet case. A similarly small restriction in the stable parameter-space for retrograde satellites is observed, where planetary close approaches in the range 2.5-4.5 mutual Hill radii destabilize most satellites orbits only if a ~ 0.65 R[subscript H]. In very close planetary pairs (e.g., the 12:11 resonance) the addition of a satellite frequently destabilizes the entire system, causing extreme close approaches and the loss of satellites over a range of circumplanetary semi-major axes. The majority of systems investigated stably harbored satellites over a wide parameter-space, suggesting that STIPs can generally offer a dynamically stable home for satellites, albeit with a slightly smaller stable parameter-space than the single-planet case. As we demonstrate that multi-planet systems are not a priori poor candidates for hosting satellites, future measurements of satellite occurrence rates in multi-planet systems versus single-planet systems could be used to constrain either satellite formation or past periods of strong dynamical interaction between planets.United States. National Aeronautics and Space Administration (Origins of Solar Systems Program Grant NNX13A124G)United States-Israel Binational Science Foundation (Grant 2012384)National Science Foundation (U.S.). Graduate Research Fellowshi

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Last time updated on 26/02/2017

This paper was published in DSpace@MIT.

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