Structural origin of relaxation in dense colloidal suspensions

Amorphous solids relax via slow molecular rearrangement induced by thermal fluctuations or applied stress. Although microscopic structural signatures predicting these structural relaxations have long been sought, a physically motivated structural measure relevant to diverse systems remains elusive. Here, we introduce a structural order parameter derived from the mean-field caging potential experienced by the particles due to their neighbors, which reliably predicts the occurrence of structural relaxations. The parameter, derived from density functional theory, is a measure of susceptibility to particle rearrangements that can effectively identify weak or defect-like regions in disordered systems. Using experiments on dense colloidal suspensions, we demonstrate a causal relationship between this order parameter and the structural relaxations of the amorphous solid. In quiescent suspensions, increasing the density leads to stronger correlations between the structure and dynamics. Under applied shear, the mean structural order parameter increases with increasing strain, signaling shear-induced softening, which is accompanied by the proliferation of plastic events. In both cases, the order parameter reliably identifies weak regions where the plastic rearrangements due to thermal fluctuation or applied shear preferentially occur. Our study paves the way to a structural understanding of the relaxation of a wide range of amorphous solids, from suspensions to metallic glasses.