Jammed particulate systems are inherently nonharmonic

Abstract

Jammed particulate systems, such as granular media, colloids, and foams, interact via one-sided forces that are nonzero only when particles overlap. We find that systems with one-sided repulsive interactions possess no linear response regime in the large system limit (N→ ∞) for all pressures p (or compressions φ), and for all N near jamming onset p→ 0. We perform simulations on 2D frictionless bidisperse mechanically stable disk packings over a range of packing fractions φ = φ-φJ above jamming onset φJ. We apply perturbations with amplitude δ to the packings along each eigen-direction from the dynamical matrix and determine whether the response of the system evolving at constant energy remains in the original eigenmode of the perturbation. For δ > δc, which we calculate analytically, a single contact breaks and fluctuations abruptly spread to all harmonic modes. As δ increases further all discrete harmonic modes disappear into a continuous frequency band. We find that <δc > φ/Nλ, where 1 > λ > 0.5, and thus jammed particulate systems are inherently nonharmonic with no linear vibrational response regime as N→ ∞ over the full range of φ, and as φ → 0 at any N.