Abstract

We study the Kozai dynamics affecting the orbital evolution of trans-neptunian objects being captured or not in MMR with Neptune. We provide energy level maps of the type (omega,q) describing the possible orbital paths from Neptune up to semimajor axis of hundreds of AU. The dynamics for non-resonant TNOs with perihelion distances, q, outside Neptune's orbit, a(N), is quite different from the dynamics of TNOs with q a(N), already studied in previous works. While for the last case there are stable equilibrium points at omega = 0 degrees, 90 degrees, 180 degrees and 270 degrees in a wide range of orbital inclinations, for the former case it appears a family of stable equilibrium points only at a specific value of the orbital inclination, i similar to 62 degrees, that we call critical inclination. We show this family of equilibrium points is generated by a mechanism analogue to which drives the dynamics of an artificial satellite perturbed by an oblate planet. The planetary system also generates an oscillation in the longitude of the perihelion of the TNOs with i similar to 46 degrees, being Eris a paradigmatic case. We discuss how the resonant condition with Neptune modify the energy level curves and the location of equilibrium points. The asymmetric librations of resonances of the type 1:N generate a distortion in the energy level curves and in the resulting location of the equilibrium points in the phase space (omega, q). We study the effect on the Kozai dynamics due to the diffusion process in a that occurs in the Scattered Disk. We show that a minimum orbital inclination is required to allow substantial variations in perihelion distances once the object is captured in MMR and that minimum inclination is greater for greater semimajor axis. (C) 2012 Elsevier Inc. All rights reserved.