Intermittent plasticity in individual grains: A study using high energy x-ray diffraction

K. Chatterjee; A. J. Beaudoin; D. C. Pagan; P. A. Shade; H. T. Philipp; M. W. Tate; S. M. Gruner; P. Kenesei; J. S. Park

doi:10.1063/1.5068756

Intermittent plasticity in individual grains: A study using high energy x-ray diffraction

K. Chatterjee, A. J. Beaudoin, D. C. Pagan, P. A. Shade, H. T. Philipp, M. W. Tate, S. M. Gruner, P. Kenesei, J. S. Park

Mechanical Science and Engineering

Research output: Contribution to journal › Article › peer-review

Abstract

Long-standing evidence suggests that plasticity in metals may proceed in an intermittent fashion. While the documentation of intermittency in plastically deforming materials has been achieved in several experimental settings, efforts to draw connections from dislocation motion and structure development to stress relaxation have been limited, especially in the bulk of deforming polycrystals. This work uses high energy x-ray diffraction measurements to build these links by characterizing plastic deformation events inside individual deforming grains in both the titanium alloy, Ti-7Al, and the magnesium alloy, AZ31. This analysis is performed by combining macroscopic stress relaxation data, complete grain stress states found using far-field high energy diffraction microscopy, and rapid x-ray diffraction spot measurements made using a Mixed-Mode Pixel Array Detector. Changes in the dislocation content within the deforming grains are monitored using the evolution of the full 3-D shapes of the diffraction spot intensity distributions in reciprocal space. The results for the Ti-7Al alloy show the presence of large stress fluctuations in contrast to AZ31, which shows a lesser degree of intermittent plastic flow.

Original language	English (US)
Article number	014501
Journal	Structural Dynamics
Volume	6
Issue number	1
DOIs	https://doi.org/10.1063/1.5068756
State	Published - Jan 1 2019

ASJC Scopus subject areas

Radiation
Instrumentation
Condensed Matter Physics
Spectroscopy

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10.1063/1.5068756

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title = "Intermittent plasticity in individual grains: A study using high energy x-ray diffraction",

abstract = "Long-standing evidence suggests that plasticity in metals may proceed in an intermittent fashion. While the documentation of intermittency in plastically deforming materials has been achieved in several experimental settings, efforts to draw connections from dislocation motion and structure development to stress relaxation have been limited, especially in the bulk of deforming polycrystals. This work uses high energy x-ray diffraction measurements to build these links by characterizing plastic deformation events inside individual deforming grains in both the titanium alloy, Ti-7Al, and the magnesium alloy, AZ31. This analysis is performed by combining macroscopic stress relaxation data, complete grain stress states found using far-field high energy diffraction microscopy, and rapid x-ray diffraction spot measurements made using a Mixed-Mode Pixel Array Detector. Changes in the dislocation content within the deforming grains are monitored using the evolution of the full 3-D shapes of the diffraction spot intensity distributions in reciprocal space. The results for the Ti-7Al alloy show the presence of large stress fluctuations in contrast to AZ31, which shows a lesser degree of intermittent plastic flow.",

author = "K. Chatterjee and Beaudoin, {A. J.} and Pagan, {D. C.} and Shade, {P. A.} and Philipp, {H. T.} and Tate, {M. W.} and Gruner, {S. M.} and P. Kenesei and Park, {J. S.}",

note = "Funding Information: A. Beaudoin and K. Chatterjee received support through the Air Force Off ice of Scientif ic Research under Contract No. FA9550-14-1-0369. P. A. Shade acknowledges support from the Materials and Manufacturing Directorate of the U.S. Air Force Research Laboratory. The use of Advance Photon Source (APS) is granted by the U.S. Department of Energy, Office of Science, Office of Basic Energy Sciences (DOE-BES) under Contract No. DE-AC02-06CH11357. Detector development at Cornell is supported by DOE-BES Grant No. DE-SC0017631 and the Cornell High Energy Synchrotron Source, which is supported by the U.S. National Science Foundation via Award No. DMR-1332208. Tim Mooney and Ron Sluiter of the APS Beamline Controls and Data Acquisition group are acknowledged for implementing the synchronized oscillation and MM-PAD data acquisition and enabling this work. Mr. Timothy Long (Cornell University) provided assistance during the experiment at APS. Conversations with Professor Robert Maass of the University of Illinois at Urbana-Champaign and Professor James Sethna of Cornell University are deeply appreciated. Publisher Copyright: {\textcopyright} 2019 Author(s).",

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AU - Gruner, S. M.

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AU - Park, J. S.

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N2 - Long-standing evidence suggests that plasticity in metals may proceed in an intermittent fashion. While the documentation of intermittency in plastically deforming materials has been achieved in several experimental settings, efforts to draw connections from dislocation motion and structure development to stress relaxation have been limited, especially in the bulk of deforming polycrystals. This work uses high energy x-ray diffraction measurements to build these links by characterizing plastic deformation events inside individual deforming grains in both the titanium alloy, Ti-7Al, and the magnesium alloy, AZ31. This analysis is performed by combining macroscopic stress relaxation data, complete grain stress states found using far-field high energy diffraction microscopy, and rapid x-ray diffraction spot measurements made using a Mixed-Mode Pixel Array Detector. Changes in the dislocation content within the deforming grains are monitored using the evolution of the full 3-D shapes of the diffraction spot intensity distributions in reciprocal space. The results for the Ti-7Al alloy show the presence of large stress fluctuations in contrast to AZ31, which shows a lesser degree of intermittent plastic flow.

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Intermittent plasticity in individual grains: A study using high energy x-ray diffraction

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