X-Ray Diffraction studies of forward and reverse plastic flow in nanoscale layers during thermal cycling

Michael D. Gram; John S. Carpenter; E. Andrew Payzant; Amit Misra; Peter M. Anderson

doi:10.1080/21663831.2013.843602

X-Ray Diffraction studies of forward and reverse plastic flow in nanoscale layers during thermal cycling

Michael D. Gram
, John S. Carpenter
, E. Andrew Payzant
, Amit Misra
, Peter M. Anderson

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

12 Scopus citations

Abstract

The biaxial stress–strain response of Cu and Ni layers within Cu/Ni nanolaminates was determined from in-plane X-ray diffraction during heating/cooling. Thinner (11nm) Cu and Ni layers with coherent, cube-on-cube interfaces reached ∼1.8GPa (Cu) and ∼2.9GPa (Ni) without yielding. Thicker (21nm) layers with semi-coherent interfaces exhibited unusual plastic phenomena, including extraordinary increases in stress during early yielding, reverse plastic flow at modest (∼12%) unloading and evidence that plastic flow in Cu layers can reduce the flow strength of adjoining Ni layers. Estimates of dislocation line energy, pinning strength, net interfacial dislocation density and hardness are provided.

Original language	English
Pages (from-to)	233-243
Number of pages	11
Journal	Materials Research Letters
Volume	1
Issue number	4
DOIs	https://doi.org/10.1080/21663831.2013.843602
State	Published - 2013

Keywords

Interface Properties
Nanolaminates
X-Ray Diffraction

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10.1080/21663831.2013.843602

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title = "X-Ray Diffraction studies of forward and reverse plastic flow in nanoscale layers during thermal cycling",

abstract = "The biaxial stress–strain response of Cu and Ni layers within Cu/Ni nanolaminates was determined from in-plane X-ray diffraction during heating/cooling. Thinner (11nm) Cu and Ni layers with coherent, cube-on-cube interfaces reached ∼1.8GPa (Cu) and ∼2.9GPa (Ni) without yielding. Thicker (21nm) layers with semi-coherent interfaces exhibited unusual plastic phenomena, including extraordinary increases in stress during early yielding, reverse plastic flow at modest (∼12\%) unloading and evidence that plastic flow in Cu layers can reduce the flow strength of adjoining Ni layers. Estimates of dislocation line energy, pinning strength, net interfacial dislocation density and hardness are provided.",

keywords = "Interface Properties, Nanolaminates, X-Ray Diffraction",

author = "Gram, \{Michael D.\} and Carpenter, \{John S.\} and Payzant, \{E. Andrew\} and Amit Misra and Anderson, \{Peter M.\}",

year = "2013",

doi = "10.1080/21663831.2013.843602",

language = "English",

volume = "1",

pages = "233--243",

journal = "Materials Research Letters",

issn = "2166-3831",

publisher = "Taylor and Francis Group",

number = "4",

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TY - JOUR

T1 - X-Ray Diffraction studies of forward and reverse plastic flow in nanoscale layers during thermal cycling

AU - Gram, Michael D.

AU - Carpenter, John S.

AU - Payzant, E. Andrew

AU - Misra, Amit

AU - Anderson, Peter M.

PY - 2013

Y1 - 2013

N2 - The biaxial stress–strain response of Cu and Ni layers within Cu/Ni nanolaminates was determined from in-plane X-ray diffraction during heating/cooling. Thinner (11nm) Cu and Ni layers with coherent, cube-on-cube interfaces reached ∼1.8GPa (Cu) and ∼2.9GPa (Ni) without yielding. Thicker (21nm) layers with semi-coherent interfaces exhibited unusual plastic phenomena, including extraordinary increases in stress during early yielding, reverse plastic flow at modest (∼12%) unloading and evidence that plastic flow in Cu layers can reduce the flow strength of adjoining Ni layers. Estimates of dislocation line energy, pinning strength, net interfacial dislocation density and hardness are provided.

AB - The biaxial stress–strain response of Cu and Ni layers within Cu/Ni nanolaminates was determined from in-plane X-ray diffraction during heating/cooling. Thinner (11nm) Cu and Ni layers with coherent, cube-on-cube interfaces reached ∼1.8GPa (Cu) and ∼2.9GPa (Ni) without yielding. Thicker (21nm) layers with semi-coherent interfaces exhibited unusual plastic phenomena, including extraordinary increases in stress during early yielding, reverse plastic flow at modest (∼12%) unloading and evidence that plastic flow in Cu layers can reduce the flow strength of adjoining Ni layers. Estimates of dislocation line energy, pinning strength, net interfacial dislocation density and hardness are provided.

KW - Interface Properties

KW - Nanolaminates

KW - X-Ray Diffraction

UR - https://www.scopus.com/pages/publications/85006703253

U2 - 10.1080/21663831.2013.843602

DO - 10.1080/21663831.2013.843602

M3 - Article

AN - SCOPUS:85006703253

SN - 2166-3831

VL - 1

SP - 233

EP - 243

JO - Materials Research Letters

JF - Materials Research Letters

IS - 4

ER -

X-Ray Diffraction studies of forward and reverse plastic flow in nanoscale layers during thermal cycling

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Keywords

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