In situ nonlinear Rayleigh wave technique to characterize the tensile plastic deformation of stainless steel 316L

TL;DR

This study develops an in situ nonlinear ultrasonic method using Rayleigh waves to monitor the evolution of dislocation structures in stainless steel 316L during tensile deformation, revealing how the acoustic nonlinearity parameter beta correlates with plastic strain.

Contribution

It introduces a novel in situ experimental setup for nonlinear ultrasonic measurements and characterizes beta's dependence on stress and microstructure during plastic deformation.

Findings

Beta decreases monotonically with plastic strain.

Beta is insensitive to stress during elastic deformation.

Beta saturates at 1.8% plastic strain, indicating dislocation structure transition.

Abstract

The acoustic nonlinearity parameter(beta) is sensitive to dislocation parameters, which continuously change during plastic deformation. Dislocation-based damage in structures/components is the source of the failure; thus, beta has been studied as a metric for non-destructive evaluation. This work consists of two parts: the development of an in situ experimental setup for nonlinear Rayleigh wave measurements, and characterization of the dependence of beta on applied stress at different levels of initial plastic strain. First, we introduce an experimental setup and methods for repeatable in situ nonlinear ultrasonic measurements. Details on design considerations and measurement schemes are provided. In the second part, beta was measured in situ during an incremental monotonic tensile test. The measured \beta monotonically decreases with plastic strain, but it is relatively insensitive to the applied stress during elastic deformation. This result highlights three aspects of the evolution of beta, which have not been sufficiently emphasized in prior work: the apparent insensitivity of beta to the applied stress during elastic deformation, decreasing beta with plastic deformation, and the saturation of beta. We attribute the trend of decreasing beta to a scaling of beta with monopole loop length during plastic deformation, which depends on initial microstructure. The saturation of beta at 1.8% coincides with a planar-to-wavy transition of dislocation structures. The in situ nonlinear ultrasonic experimental method presented in this work is significant as the in situ results can provide broader insights on beta and dislocation-based damage evolution than ex situ measurements alone.