Energetics of particle-size segregation

Abstract

We introduce a continuum framework for the energetics of particle-size segregation in bidisperse granular flows. Building on continuum segregation equations and a recent segregation flux model, the proposed framework offers general analytical expressions to study the physics of granular flows from a mechanical energy perspective. To demonstrate the framework's applicability, we examined the energetics in shear-driven flows. Numerical experiments with varying frictional coefficients and particle-size ratios revealed two distinct phases in the associated energetics with particle segregation and diffusive remixing, and that the potential energy to the kinetic energy ratio in the steady state follows the scaling relationship E(s)gp / E(s)k Pe-1/2sr for 0.4 ≤ Pesr ≤ 300, the segregation-rheology P\'eclet number. Our findings hint that the bulk segregation-mixing state can be predicted and controlled using Pesr, determined from known system parameters, providing a impactful tool for engineering and geophysical applications.