Inertia damping systems and methods

What is claimed is: 1. A downhole inertia damping system, comprising: a collar positioned axially between a downhole tool and a bit; and a damper coupled to the collar, the damper comprising: a mandrel disposed in the collar, the mandrel and the collar defining an internal chamber therebetween; a first inertia ring disposed around the mandrel inside the internal chamber, the first inertia ring being rotatable within the internal chamber and relative to the collar; a second inertia ring disposed around the mandrel inside the internal chamber, the second inertia ring being rotatable within the internal chamber and relative to the collar; a bearing element disposed around the mandrel in the internal chamber and extending between the mandrel and the collar to separate the first inertia ring from the second inertia ring; a bushing disposed on the first inertia ring or the second inertia ring, the bushing configured to contact the bearing element; and a torsion fluid contained within the internal chamber and in contact with the first inertia ring, and in contact with the second inertia ring via a plurality of openings in the bearing element. 2. The downhole inertia damping system of claim 1 , the damper being located closer to the downhole tool than to the bit. 3. The downhole inertia damping system of claim 1 , wherein the mandrel comprises an outer surface and an inner surface, the inner surface defining a bore. 4. The downhole inertia damping system of claim 3 , wherein the bearing element is engaged with an inner surface of the collar and the outer surface of the mandrel. 5. The downhole inertia damping system of claim 3 , the damper further comprising a spacer coupled to the mandrel. 6. The downhole inertia damping system of claim 5 , wherein the bearing element is attached to the spacer. 7. The downhole inertia damping system of claim 1 , the bearing element further including a surface defining a plurality of channels, the surface facing one of the first inertia ring or the second inertia ring. 8. A method for damping oscillations, comprising: rotating a collar downhole that is connected to a damper and positioned axially between a downhole tool and a bit, the damper comprising: a mandrel disposed in the collar, the mandrel including a first surface, and the first surface and the collar defining an internal chamber therebetween; a first inertia ring disposed around the mandrel inside the internal chamber, the first inertia ring being rotatable within the internal chamber and relative to the collar; a second inertia ring disposed around the mandrel inside the internal chamber, the second inertia ring being rotatable within the internal chamber and relative to the collar; a bearing element disposed around the mandrel in the internal chamber, and extending between the mandrel and the collar to separate the first inertia ring from the second inertia ring; a bushing disposed on the first inertia ring or the second inertia ring, the bushing configured to contact the bearing element; and a torsion fluid contained within the internal chamber and in contact with the first inertia ring, and in contact with the second inertia ring via a plurality of openings in the bearing element; and in response to rotating the collar, rotating the first inertia ring and the second inertia ring out of sync with the rotation of the collar. 9. The method of claim 8 , further comprising: rotating the first inertia ring at a first rotational rate; and rotating the second inertia ring at a second rotational rate, the second rotational rate being different than the first rotational rate. 10. The method of claim 8 , further comprising: flowing a drilling fluid through a central bore in the mandrel defined by a second surface of the mandrel, the drilling fluid being separated from the internal chamber by a wall of the mandrel.