Rheology of periodically sheared suspensions undergoing reversible-irreversible transition

Abstract

The rheology of non-colloidal suspensions under cyclic shear is studied numerically. The main findings are a strain amplitude (γ0) dependent response in the shear stress and second normal stress difference (N2). Specifically, we find a reduced viscosity, an enhanced intracycle shear thinning, the onset of a finite N2 and its frequency doubling, all near a critical strain amplitude γc that scales with the volume fraction φ as γc φ-2. These rheological changes also signify a reversible-irreversible transition (RIT), dividing stroboscopic particle dynamics into a reversible absorbing phase (for γ0<γc) and a persistently diffusing phase (for γ0>γc). We explain the results based on two flow-induced mechanisms and elucidate their connection in the context of RIT through the underlying microstructure, which tends towards hyperuniformity near γ0=γc. Overall, we expect this correspondence between rheology and emergent dynamics to hold in a wide range of settings where structural organizations are dominated by volume exclusions.