Mechanical Metrics of Virtual Polycrystals (MechMet)

Paul R. Dawson; Matthew P. Miller; Tresa M. Pollock; Joe Wendorf; Leah H. Mills; Jean Charles Stinville; Marie Agathe Charpagne; McLean L.P. Echlin

doi:10.1007/s40192-021-00206-7

Mechanical Metrics of Virtual Polycrystals (MechMet)

Paul R. Dawson, Matthew P. Miller, Tresa M. Pollock, Joe Wendorf, Leah H. Mills, Jean Charles Stinville, Marie Agathe Charpagne, McLean L.P. Echlin

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

Abstract

The details of polycrystalline microstructure often influence the early stages of yielding and strain localization under monotonic and cyclic loading, particularly in elastically anisotropic materials. A new software package, MechMet (mechanical metrics) provides a convenient finite element tool for solving field equations for elasticity in polycrystals in conjunction with investigations of microstructure-induced heterogeneity. The simulated displacement field is used to compute several mechanical metrics, such as the strain and stress tensors, directional stiffness, relative Schmid factor, and the directional strength-to-stiffness ratio. The virtual polycrystal finite element meshes needed by MechMet can be created with the Neper package or any other method that produces a 10-node, tetrahedral, serendipity element. Formatted output files are automatically generated for visualization with Paraview or VisIt. This paper presents an overview of the MechMet package and its application to polycrystalline materials of both cubic and hexagonal structures.

Original language	English (US)
Pages (from-to)	265-285
Number of pages	21
Journal	Integrating Materials and Manufacturing Innovation
Volume	10
Issue number	2
Early online date	Apr 22 2021
DOIs	https://doi.org/10.1007/s40192-021-00206-7
State	Published - Jun 2021
Externally published	Yes

Keywords

Elastic modulus
FEpX
Finite element
Mechanical properties
Neper
Stiffness

ASJC Scopus subject areas

General Materials Science
Industrial and Manufacturing Engineering

Online availability

10.1007/s40192-021-00206-7

Library availability

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Cite this

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title = "Mechanical Metrics of Virtual Polycrystals (MechMet)",

abstract = "The details of polycrystalline microstructure often influence the early stages of yielding and strain localization under monotonic and cyclic loading, particularly in elastically anisotropic materials. A new software package, MechMet (mechanical metrics) provides a convenient finite element tool for solving field equations for elasticity in polycrystals in conjunction with investigations of microstructure-induced heterogeneity. The simulated displacement field is used to compute several mechanical metrics, such as the strain and stress tensors, directional stiffness, relative Schmid factor, and the directional strength-to-stiffness ratio. The virtual polycrystal finite element meshes needed by MechMet can be created with the Neper package or any other method that produces a 10-node, tetrahedral, serendipity element. Formatted output files are automatically generated for visualization with Paraview or VisIt. This paper presents an overview of the MechMet package and its application to polycrystalline materials of both cubic and hexagonal structures.",

keywords = "Elastic modulus, FEpX, Finite element, Mechanical properties, Neper, Stiffness",

author = "Dawson, {Paul R.} and Miller, {Matthew P.} and Pollock, {Tresa M.} and Joe Wendorf and Mills, {Leah H.} and Stinville, {Jean Charles} and Charpagne, {Marie Agathe} and Echlin, {McLean L.P.}",

note = "Funding Information: The Cornell University contributors{\textquoteright} research was supported by the ONR under Grant # N00014-16-1-3126, Dr. William Mullins Program Manager. The HEDM experiments on Ti-7Al were conducted at the Center for High Energy X-ray Sciences (CHEXS) which is supported by the National Science Foundation under award DMR-1829070. The UC Santa Barbara contributors acknowledge the support of Office of Naval Research Grants# N00014-19-1-2129 and N00014-18-1-2392 and National Science Foundation grant 1934641. The MRL Shared Experimental Facilities at UC Santa Barbara are supported by the MRSEC Program of the NSF under Award No. DMR 1720256, a member of the NSF-funded Materials Research Facilities Network (www.mrfn.org). Use was made of computational facilities purchased with funds from the National Science Foundation (CNS-1725797) and administered by the Center for Scientific Computing (CSC). The CSC is supported by the California NanoSystems Institute and the Materials Research Science and Engineering Center (MRSEC; NSF DMR 1720256) at UC Santa Barbara. Publisher Copyright: {\textcopyright} 2021, The Minerals, Metals & Materials Society.",

year = "2021",

month = jun,

doi = "10.1007/s40192-021-00206-7",

language = "English (US)",

volume = "10",

pages = "265--285",

journal = "Integrating Materials and Manufacturing Innovation",

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AU - Dawson, Paul R.

AU - Miller, Matthew P.

AU - Pollock, Tresa M.

AU - Wendorf, Joe

AU - Mills, Leah H.

AU - Stinville, Jean Charles

AU - Charpagne, Marie Agathe

AU - Echlin, McLean L.P.

N1 - Funding Information: The Cornell University contributors’ research was supported by the ONR under Grant # N00014-16-1-3126, Dr. William Mullins Program Manager. The HEDM experiments on Ti-7Al were conducted at the Center for High Energy X-ray Sciences (CHEXS) which is supported by the National Science Foundation under award DMR-1829070. The UC Santa Barbara contributors acknowledge the support of Office of Naval Research Grants# N00014-19-1-2129 and N00014-18-1-2392 and National Science Foundation grant 1934641. The MRL Shared Experimental Facilities at UC Santa Barbara are supported by the MRSEC Program of the NSF under Award No. DMR 1720256, a member of the NSF-funded Materials Research Facilities Network (www.mrfn.org). Use was made of computational facilities purchased with funds from the National Science Foundation (CNS-1725797) and administered by the Center for Scientific Computing (CSC). The CSC is supported by the California NanoSystems Institute and the Materials Research Science and Engineering Center (MRSEC; NSF DMR 1720256) at UC Santa Barbara. Publisher Copyright: © 2021, The Minerals, Metals & Materials Society.

PY - 2021/6

Y1 - 2021/6

N2 - The details of polycrystalline microstructure often influence the early stages of yielding and strain localization under monotonic and cyclic loading, particularly in elastically anisotropic materials. A new software package, MechMet (mechanical metrics) provides a convenient finite element tool for solving field equations for elasticity in polycrystals in conjunction with investigations of microstructure-induced heterogeneity. The simulated displacement field is used to compute several mechanical metrics, such as the strain and stress tensors, directional stiffness, relative Schmid factor, and the directional strength-to-stiffness ratio. The virtual polycrystal finite element meshes needed by MechMet can be created with the Neper package or any other method that produces a 10-node, tetrahedral, serendipity element. Formatted output files are automatically generated for visualization with Paraview or VisIt. This paper presents an overview of the MechMet package and its application to polycrystalline materials of both cubic and hexagonal structures.

AB - The details of polycrystalline microstructure often influence the early stages of yielding and strain localization under monotonic and cyclic loading, particularly in elastically anisotropic materials. A new software package, MechMet (mechanical metrics) provides a convenient finite element tool for solving field equations for elasticity in polycrystals in conjunction with investigations of microstructure-induced heterogeneity. The simulated displacement field is used to compute several mechanical metrics, such as the strain and stress tensors, directional stiffness, relative Schmid factor, and the directional strength-to-stiffness ratio. The virtual polycrystal finite element meshes needed by MechMet can be created with the Neper package or any other method that produces a 10-node, tetrahedral, serendipity element. Formatted output files are automatically generated for visualization with Paraview or VisIt. This paper presents an overview of the MechMet package and its application to polycrystalline materials of both cubic and hexagonal structures.

KW - Elastic modulus

KW - FEpX

KW - Finite element

KW - Mechanical properties

KW - Neper

KW - Stiffness

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ER -

Mechanical Metrics of Virtual Polycrystals (MechMet)

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