Mechanistic diffusion model for slow dynamic behavior in materials

•The Mechanistic Diffusion Model provides deeper understanding of transient slow dynamic nonlinear behaviors.•Conditioning and recovery periods of slow dynamics are modeled considering environmental effects using a unified theory.•The MDM model is validated through new experimental measurements. Inf...

Full description

Saved in:
Bibliographic Details
Published in:Journal of the mechanics and physics of solids 2021-05, Vol.150, p.104355, Article 104355
Main Authors: Bittner, J.A., Popovics, J.S.
Format: Article
Language:English
Subjects:
Analytic functions (C)
Contact mechanics (B)
Diffusion (A)
Diffusion rate
Equilibrium conditions
Humidity
Hysteresis
Moisture
Nonlinear dynamics
Nonlinearity
Phase transformation (A)
Stress-strain relationships
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:•The Mechanistic Diffusion Model provides deeper understanding of transient slow dynamic nonlinear behaviors.•Conditioning and recovery periods of slow dynamics are modeled considering environmental effects using a unified theory.•The MDM model is validated through new experimental measurements. Infrastructure materials, such as rocks and concrete, exhibit an array of intricate and interrelated dynamic mechanical behaviors that act across a broad range of size scales. Modeling these dynamic behaviors is important for understanding safe design, application, and maintenance practices. One particular and fascinating nonlinear dynamic mechanic response - slow dynamics - is characterized by a self-recovering hysteretic stress-strain relationship. Here we formulate a mechanistic model for slow dynamics, which we call a mechanistic diffusion model (MDM), based on coupled mechanical and diffusional processes. Diffusion-driven moisture migration nearby the minuscule regions surrounding granular contact points within a cracked solid serves as the physical foundation of the model. Diffusion physics explains fast conditioning rates, as moisture is vaporized, and relatively slow recovery process rates, as the moisture condenses back to equilibrium conditions. The MDM provides physically-based justification for environment and strain activated observations noted in previous slow dynamic experiments. The MDM is verified against new experimental data of internal humidity and mechanical softening observed in a porous solid during dynamic excitation. The MDM model predicts, and the accompanying experiment successfully exhibits, internal humidity changes with slow dynamic nonlinearity of the test material. The MDM model identifies a physical mechanism of transient nonlinearity and provides a framework to interpret the significance of observed slow dynamic nonlinear behaviors.
ISSN:0022-5096
1873-4782
DOI:10.1016/j.jmps.2021.104355