The distribution of forces affects vibrational properties in hard sphere glasses

Abstract

We study theoretically and numerically the elastic properties of hard sphere glasses, and provide a real-space description of their mechanical stability. In contrast to repulsive particles at zero-temperature, we argue that the presence of certain pairs of particles interacting with a small force f soften elastic properties. This softening affects the exponents characterizing elasticity at high pressure, leading to experimentally testable predictions. Denoting P(f) fθe the force distribution of such pairs and φc the packing fraction at which pressure diverges, we predict that (i) the density of states has a low-frequency peak at a scale ω*, rising up to it as D(ω) ω2+a, and decaying above ω* as D(ω) ω-a where a=(1-θe)/(3+θe) and ω is the frequency, (ii) shear modulus and mean-squared displacement are inversely proportional with δ R21/μ (φc-φ) where =2-2/(3+θe), and (iii) continuum elasticity breaks down on a scale c 1/δ z (φc-φ)-b where b=(1+θe)/(6+2θe) and δ z=z-2d, where z is the coordination and d the spatial dimension. We numerically test (i) and provide data supporting that θe≈ 0.41 in our bi-disperse system, independently of system preparation in two and three dimensions, leading to ≈1.41, a ≈ 0.17, and b≈ 0.21. Our results for the mean-square displacement are consistent with a recent exact replica computation for d=∞, whereas some observations differ, as rationalized by the present approach.