Elastic Moduli and Vibrational Modes in Jammed Particulate Packings

Abstract

When we elastically impose a homogeneous, affine deformation on amorphous solids, they also undergo an inhomogeneous, non-affine deformation, which can have a crucial impact on the overall elastic response. To correctly understand the elastic modulus M, it is therefore necessary to take into account not only the affine modulus MA, but also the non-affine modulus MN that arises from the non-affine deformation. In the present work, we study the bulk (M=K) and shear (M=G) moduli in static jammed particulate packings over a range of packing fractions . One novelty of this work is to elucidate the contribution of each vibrational mode to the non-affine MN through a modal decomposition of the displacement and force fields. In the vicinity of the (un)jamming transition, c, the vibrational density of states, g(ω), shows a plateau in the intermediate frequency regime above a characteristic frequency ω. We illustrate that this unusual feature apparent in g(ω) is reflected in the behavior of MN: As → c, where ω → 0, those modes for ω < ω contribute less and less, while contributions from those for ω > ω approach a constant value which results in MN to approach a critical value MNc, as MN-MNc ω. At c itself, the bulk modulus attains a finite value Kc=KAc-KNc > 0, such that KNc has a value that remains below KAc. In contrast, for the critical shear modulus Gc, GNc and GAc approach the same value so that the total value becomes exactly zero, Gc = GAc-GNc =0. We explore what features of the configurational and vibrational properties cause such the distinction between K and G, allowing us to validate analytical expressions for their critical values.