Shape-preserving machining produces gradient nanolaminate medium entropy alloys with high strain hardening capability

Wei Guo; Zongrui Pei; Xiahan Sang; Jonathan D. Poplawsky; Stefanie Bruschi; Jun Qu; Dierk Raabe; Hongbin Bei

doi:10.1016/j.actamat.2019.03.024

Shape-preserving machining produces gradient nanolaminate medium entropy alloys with high strain hardening capability

Wei Guo, Zongrui Pei, Xiahan Sang, Jonathan D. Poplawsky, Stefanie Bruschi, Jun Qu, Dierk Raabe, Hongbin Bei

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

45 Scopus citations

Abstract

A high density of grain boundaries can potentially increase structural materials' strength, but at the expense of losing the materials' strain hardening ability at high flow stress levels. However, endowing materials with grain size gradients and a high density of internal interfaces can simultaneously increase the strength and strain hardening ability. This applies particularly for through-thickness gradients of nanoscale interface structures. Here we apply a machining method that produces metals with nanoscale interface gradients. Conventional bulk plastic deformation such as rolling, a process applied annually to about 2 billion tons of material, aims to reduce the metal thickness. We have modified this process by introducing severe strain path changes, realized by leading the sheet through a U-turn while preserving its shape, an approach known as ‘hard turning’. We applied this process at both room temperature and 77 K to a NiCrCo medium entropy alloy. Micropillar compression was conducted to evaluate the mechanical response. After hard turning at room temperature, the surface microstructure obtained a ∼50% increase in yield stress (0.9 GPa) over the original state with homogeneous grain size (0.4 GPa), but the initial strain hardening rate did not show significant improvement. However, after hard turning at 77 k, the gradient nanolaminate structure tripled in yield stress and more than doubled its initial strain hardening rate. The improvements were achieved by introducing a specific microstructure that consists of gradient nanolaminates in the form of nanospaced twins and martensite in the face center cubic (fcc) phase. This microstructure was formed only at cryogenic temperature. It was found after turning at room temperature that only nanospaced twins were present in the fcc phase inside nanolaminates that had formed at the surface. The origin of the enhanced strain hardening mechanism was studied. Joint density functional theory (DFT) and axial next nearest neighbor Ising (ANNNI) models were used to explain the temperature-dependent phase formation of the NiCrCo nanolaminate at the surface of the hard-turned material.

Original language	English
Pages (from-to)	176-186
Number of pages	11
Journal	Acta Materialia
Volume	170
DOIs	https://doi.org/10.1016/j.actamat.2019.03.024
State	Published - May 15 2019

Funding

This manuscript has been authored by UT-Battelle, LLC under Contract No. DE-AC05-00OR22725 with the U.S. Department of Energy. The United States Government retains and the publisher, by accepting the article for publication, acknowledges that the United States Government retains a non-exclusive, paid-up, irrevocable, world-wide license to publish or reproduce the published form of this manuscript, or allow others to do so, for United States Government purposes. The Department of Energy will provide public access to these results of federally sponsored research in accordance with the DOE Public Access Plan (http://energy.gov/downloads/doe-public-access-plan).The authors are grateful for the discussion with Dr. Vikram Bedekar, Robert A. Pendergrass, and Andrew A. Markja at the Timken Company. This research was supported primarily by the U.S. Department of Energy, Office of Science, Basic Energy Sciences, Materials Sciences and Engineering Division. Electron microscopy and atom probe tomography experiments were conducted at ORNL's Center for Nanophase Materials Sciences (CNMS), which is a U.S. Department of Energy Office of Science User Facility. The authors are grateful for the discussion with Dr. Vikram Bedekar, Robert A. Pendergrass, and Andrew A. Markja at the Timken Company. This research was supported primarily by the U.S. Department of Energy, Office of Science, Basic Energy Sciences, Materials Sciences and Engineering Division . Electron microscopy and atom probe tomography experiments were conducted at ORNL’s Center for Nanophase Materials Sciences (CNMS), which is a U.S. Department of Energy Office of Science User Facility.

Keywords

Cryogenic hard turning
Medium entropy alloys
Nanolaminates
Phase transformations
Transmission electron microscopy

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title = "Shape-preserving machining produces gradient nanolaminate medium entropy alloys with high strain hardening capability",

abstract = "A high density of grain boundaries can potentially increase structural materials' strength, but at the expense of losing the materials' strain hardening ability at high flow stress levels. However, endowing materials with grain size gradients and a high density of internal interfaces can simultaneously increase the strength and strain hardening ability. This applies particularly for through-thickness gradients of nanoscale interface structures. Here we apply a machining method that produces metals with nanoscale interface gradients. Conventional bulk plastic deformation such as rolling, a process applied annually to about 2 billion tons of material, aims to reduce the metal thickness. We have modified this process by introducing severe strain path changes, realized by leading the sheet through a U-turn while preserving its shape, an approach known as {\textquoteleft}hard turning{\textquoteright}. We applied this process at both room temperature and 77 K to a NiCrCo medium entropy alloy. Micropillar compression was conducted to evaluate the mechanical response. After hard turning at room temperature, the surface microstructure obtained a ∼50% increase in yield stress (0.9 GPa) over the original state with homogeneous grain size (0.4 GPa), but the initial strain hardening rate did not show significant improvement. However, after hard turning at 77 k, the gradient nanolaminate structure tripled in yield stress and more than doubled its initial strain hardening rate. The improvements were achieved by introducing a specific microstructure that consists of gradient nanolaminates in the form of nanospaced twins and martensite in the face center cubic (fcc) phase. This microstructure was formed only at cryogenic temperature. It was found after turning at room temperature that only nanospaced twins were present in the fcc phase inside nanolaminates that had formed at the surface. The origin of the enhanced strain hardening mechanism was studied. Joint density functional theory (DFT) and axial next nearest neighbor Ising (ANNNI) models were used to explain the temperature-dependent phase formation of the NiCrCo nanolaminate at the surface of the hard-turned material.",

keywords = "Cryogenic hard turning, Medium entropy alloys, Nanolaminates, Phase transformations, Transmission electron microscopy",

author = "Wei Guo and Zongrui Pei and Xiahan Sang and Poplawsky, {Jonathan D.} and Stefanie Bruschi and Jun Qu and Dierk Raabe and Hongbin Bei",

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T1 - Shape-preserving machining produces gradient nanolaminate medium entropy alloys with high strain hardening capability

AU - Guo, Wei

AU - Pei, Zongrui

AU - Sang, Xiahan

AU - Poplawsky, Jonathan D.

AU - Bruschi, Stefanie

AU - Qu, Jun

AU - Raabe, Dierk

AU - Bei, Hongbin

PY - 2019/5/15

Y1 - 2019/5/15

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AB - A high density of grain boundaries can potentially increase structural materials' strength, but at the expense of losing the materials' strain hardening ability at high flow stress levels. However, endowing materials with grain size gradients and a high density of internal interfaces can simultaneously increase the strength and strain hardening ability. This applies particularly for through-thickness gradients of nanoscale interface structures. Here we apply a machining method that produces metals with nanoscale interface gradients. Conventional bulk plastic deformation such as rolling, a process applied annually to about 2 billion tons of material, aims to reduce the metal thickness. We have modified this process by introducing severe strain path changes, realized by leading the sheet through a U-turn while preserving its shape, an approach known as ‘hard turning’. We applied this process at both room temperature and 77 K to a NiCrCo medium entropy alloy. Micropillar compression was conducted to evaluate the mechanical response. After hard turning at room temperature, the surface microstructure obtained a ∼50% increase in yield stress (0.9 GPa) over the original state with homogeneous grain size (0.4 GPa), but the initial strain hardening rate did not show significant improvement. However, after hard turning at 77 k, the gradient nanolaminate structure tripled in yield stress and more than doubled its initial strain hardening rate. The improvements were achieved by introducing a specific microstructure that consists of gradient nanolaminates in the form of nanospaced twins and martensite in the face center cubic (fcc) phase. This microstructure was formed only at cryogenic temperature. It was found after turning at room temperature that only nanospaced twins were present in the fcc phase inside nanolaminates that had formed at the surface. The origin of the enhanced strain hardening mechanism was studied. Joint density functional theory (DFT) and axial next nearest neighbor Ising (ANNNI) models were used to explain the temperature-dependent phase formation of the NiCrCo nanolaminate at the surface of the hard-turned material.

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KW - Medium entropy alloys

KW - Nanolaminates

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KW - Transmission electron microscopy

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ER -

Shape-preserving machining produces gradient nanolaminate medium entropy alloys with high strain hardening capability

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