Slow dynamic elastic recovery in unconsolidated metal structures

TL;DR

This study investigates slow dynamic elastic recovery in unconsolidated metallic structures, revealing universal behavior across different materials and suggesting mechanisms beyond glassy microstructures and cracking.

Contribution

It provides experimental evidence of slow nonlinear elastic recovery in metallic systems, challenging previous assumptions about the necessity of glassy microstructures.

Findings

Universal logarithmic-in-time recovery observed

Glass microstructures and cracking are not essential

Ultrasonic coda wave interferometry effectively detects slow dynamics

Abstract

Slow dynamic nonlinearity is widely observed in brittle materials with complex heterogeneous or cracked microstructures. It is seen in rocks, concrete and cracked glass blocks. Unconsolidated structures show the behavior as well: aggregates of glass beads under pressure and a single glass bead confined between two glass plates. A defining feature is the loss of stiffness after a mechanical conditioning, followed by a logarithmic-in-time recovery. Materials observed to exhibit slow dynamics are sufficiently different in microstructure, chemical composition, and scale (ranging from the laboratory to the seismological) to suggest some kind of universality. There lacks a full theoretical understanding of the universality in general and the log(time) recovery in particular; one suspicion has been that the phenomenon is associated with glassy grain boundaries and microcracking. Seminal studies were focused on sandstones and other natural rocks, but in recent years other experimental venues have been introduced with which to inform theory. Here, we present measurements on some simple metallic systems: an unconsolidated aggregate of aluminum beads under a confining pressure, and an aluminum bead confined between two aluminum plates, and a steel bead confined between steel plates. Ultrasonic waves are used as probes of the systems, and changes are assessed with coda wave interferometry. Three different methods of low-frequency conditioning are applied; all reveal slow dynamic nonlinearities. Results imply that glassy microstructures and cracking do not play essential roles, as they would appear to be absent in our systems.