Rigid Spheres Rising at Constant Speed Through Collections of Hydrogels

We present the results of an experimental investigation into buoyant rigid spheres rising through concentrated collections of hydrated hydrogel particles. The volume fraction of particles is such that the mechanical properties of the material are intermediate between a very viscous fluid and a soft solid. Despite the non-Newtonian character of these hydrogels, we find that when the surface of the material is free, an immersed buoyant sphere rises with a constant speed. The effects of the motion in the surrounding material are observed to be highly localized around the sphere. When the mass of the sphere is varied, its terminal velocity is observed to depend exponentially on the buoyancy. Qualitatively distinct behavior is found when a lid is present on the surface of the material, and in this case, a sublinear time dependence of the displacement is found. Linear motion of the sphere is accompanied by flow at the surface of the material whereas fluid movement is suppressed when a lid is applied. Other boundary condition variations are consistent with the perspective that constant speed motion is induced by the presence of a free boundary.