Rate-independent hysteretic energy dissipation in collagen fibrils

TL;DR

This paper uncovers a rate-independent hysteretic energy dissipation mechanism in collagen fibrils, modeled through a generic force-distance hysteresis model that predicts energy loss during nanoindentation.

Contribution

It introduces a novel, unified model for energy dissipation in collagen fibrils that is independent of indentation rate and accounts for nonlinear history dependence.

Findings

Hysteresis is rate-independent at velocities below 1 μm/s.

The model accurately predicts force and energy dissipation for various indentation paths.

Energy dissipation depends nonlinearly on indentation history and amplitude.

Abstract

Nanoindentation cycles measured with an atomic force microscope on hydrated collagen fibrils exhibit a rate-independent hysteresis with return point memory. This previously unknown energy dissipation mechanism describes in unified form elastoplastic indentation, capillary adhesion, and surface leveling at indentation velocities smaller than 1 $\mu$m s$^{-1}$, where viscous friction is negligible. A generic hysteresis model, based on force-distance data measured during one large approach-retract cycle, predicts the force (output) and the dissipated energy for arbitrary indentation trajectories (input). While both quantities are rate independent, they do depend nonlinearly on indentation history and on indentation amplitude.