The curiously warped mean plane of the Kuiper belt

Abstract

We measured the mean plane of the Kuiper belt as a function of semi-major axis. For the classical Kuiper belt as a whole (the non-resonant objects in the semi-major axis range 42--48~au), we find a mean plane of inclination im=1.8^+0.7-0.4 and longitude of ascending node m=77^+18-14 (in the J2000 ecliptic-equinox coordinate system), in accord with theoretical expectations of the secular effects of the known planets. With finer semi-major axis bins, we detect a statistically significant warp in the mean plane near semi-major axes 40--42~au. Linear secular theory predicts a warp near this location due to the 18 nodal secular resonance, however the measured mean plane for the 40.3-42~au semi-major axis bin (just outside the 18) is inclined 13 to the predicted plane, a nearly 3-σ discrepancy. For the more distant Kuiper belt objects of semi-major axes in the range 50--80~au, the expected mean plane is close to the invariable plane of the solar system, but the measured mean plane deviates greatly from this: it has inclination im=9.1^+6.6-3.8 and longitude of ascending node m=227^+18-44. We estimate this deviation from the expected mean plane to be statistically significant at the 97-99\% confidence level. We discuss several possible explanations for this deviation, including the possibility that a relatively close-in (a100~au), unseen small planetary-mass object in the outer solar system is responsible for the warping.