Abstract
Abstract Both physical and dynamical properties must be considered to constrain the origins of the dynamically excited distant solar system populations. We present high-precision (g–r) colors for 25 small (H r > 5) dynamically excited trans-Neptunian objects (TNOs) and centaurs acquired as part of the Colours of the Outer Solar System Origins Survey. We combine our data set with previously published measurements and consider a set of 229 colors of outer solar system objects on dynamically excited orbits. The overall color distribution is bimodal and can be decomposed into two distinct classes, termed gray and red, that each has a normal color distribution. The two color classes have different inclination distributions: red objects have lower inclinations than the gray ones. This trend holds for all dynamically excited TNO populations. Even in the worst-case scenario, biases in the discovery surveys cannot account for this trend; it is intrinsic to the TNO population. Considering that TNOs are the precursors of centaurs, and that their inclinations are roughly preserved as they become centaurs, our finding solves the conundrum of centaurs being the only outer solar system population identified so far to exhibit this property. The different orbital distributions of the gray and red dynamically excited TNOs provide strong evidence that their colors are due to different formation locations in a disk of planetesimals with a compositional gradient.
Highlights
Trans-Neptunian objects (TNOs) represent some of the most unaltered remnants of the planetary formation process
How would such a signal appear after the scattering of centaurs from the Kuiper Belt? Here, we have shown that this dichotomy exists in the Kuiper Belt, and that it appears to be a common feature to all dynamical classes of the dynamically hot TNOs
We report new (g–r) colors for 25 small (Hmag > 5) dynamically excited TNOs observed in the Col-Outer Solar System Origin Survey (OSSOS) survey
Summary
Trans-Neptunian objects (TNOs) represent some of the most unaltered remnants of the planetary formation process. Different formation locations might correspond to distinct surface compositions, though this remains disputed (Gil-Hutton 2002; Stern 2002; Trujillo & Brown 2002; Delsanti et al 2004; Santos-Sanz et al 2009) As such, both physical and dynamical properties must be considered to constrain the origins of TNOs. Unlike the majority of the known dwarf-planet-sized bodies, the smaller TNOs are too faint to be studied through optical and infrared. The TNOs can be divided into two broad dynamical groups of objects: the dynamically quiescent cold classicals, and the dynamically excited hot population (Tegler & Romanishin 2000; Brown 2001). This has strong implications for the origins of the dynamically excited TNO populations (Section 4)
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