Residual stress and subsurface damage in machined alumina and alumina/silicon carbide nanocomposite ceramics

H. Wu; S. G. Roberts; B. Derby

doi:10.1016/S1359-6454(00)00333-5

Residual stress and subsurface damage in machined alumina and alumina/silicon carbide nanocomposite ceramics

H. Wu, S. G. Roberts, B. Derby^*

^*Corresponding author for this work

Materials Engineering

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

Abstract

We have used TEM and Hertzian indentation to study the interrelation between subsurface damage and residual stress introduced by grinding and diamond polishing surfaces of polycrystalline alumina and 5%SiC/alumina nanocomposites. In all cases a layer of high dislocation density was found near the surface. This varied in thickness from about 300 nm for alumina polished with 1 μm diamond grit to greater than 6 μm for a nanocomposite surface wheel-ground with 150 μm diamond grit. For a given finishing process the nanocomposites showed a greater depth of dislocation activity than alumina. In alumina, extensive basal twinning was found beneath the ground surfaces. Hertzian indentation data indicates a residual compressive stress of about 1500 MPa confined to the dislocation-containing region. Mechanisms for the enhanced dislocation activity in the nanocomposites are discussed.

Original language	English
Pages (from-to)	507-517
Number of pages	11
Journal	Acta Materialia
Volume	49
Issue number	3
DOIs	https://doi.org/10.1016/S1359-6454(00)00333-5
Publication status	Published - 8 Feb 2001

Keywords

residual stress
transmission electron microscopy (TEM)
dislocations
ceramics
microstructure

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title = "Residual stress and subsurface damage in machined alumina and alumina/silicon carbide nanocomposite ceramics",

abstract = "We have used TEM and Hertzian indentation to study the interrelation between subsurface damage and residual stress introduced by grinding and diamond polishing surfaces of polycrystalline alumina and 5%SiC/alumina nanocomposites. In all cases a layer of high dislocation density was found near the surface. This varied in thickness from about 300 nm for alumina polished with 1 μm diamond grit to greater than 6 μm for a nanocomposite surface wheel-ground with 150 μm diamond grit. For a given finishing process the nanocomposites showed a greater depth of dislocation activity than alumina. In alumina, extensive basal twinning was found beneath the ground surfaces. Hertzian indentation data indicates a residual compressive stress of about 1500 MPa confined to the dislocation-containing region. Mechanisms for the enhanced dislocation activity in the nanocomposites are discussed.",

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author = "H. Wu and Roberts, {S. G.} and B. Derby",

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TY - JOUR

T1 - Residual stress and subsurface damage in machined alumina and alumina/silicon carbide nanocomposite ceramics

AU - Wu, H.

AU - Roberts, S. G.

AU - Derby, B.

PY - 2001/2/8

Y1 - 2001/2/8

N2 - We have used TEM and Hertzian indentation to study the interrelation between subsurface damage and residual stress introduced by grinding and diamond polishing surfaces of polycrystalline alumina and 5%SiC/alumina nanocomposites. In all cases a layer of high dislocation density was found near the surface. This varied in thickness from about 300 nm for alumina polished with 1 μm diamond grit to greater than 6 μm for a nanocomposite surface wheel-ground with 150 μm diamond grit. For a given finishing process the nanocomposites showed a greater depth of dislocation activity than alumina. In alumina, extensive basal twinning was found beneath the ground surfaces. Hertzian indentation data indicates a residual compressive stress of about 1500 MPa confined to the dislocation-containing region. Mechanisms for the enhanced dislocation activity in the nanocomposites are discussed.

AB - We have used TEM and Hertzian indentation to study the interrelation between subsurface damage and residual stress introduced by grinding and diamond polishing surfaces of polycrystalline alumina and 5%SiC/alumina nanocomposites. In all cases a layer of high dislocation density was found near the surface. This varied in thickness from about 300 nm for alumina polished with 1 μm diamond grit to greater than 6 μm for a nanocomposite surface wheel-ground with 150 μm diamond grit. For a given finishing process the nanocomposites showed a greater depth of dislocation activity than alumina. In alumina, extensive basal twinning was found beneath the ground surfaces. Hertzian indentation data indicates a residual compressive stress of about 1500 MPa confined to the dislocation-containing region. Mechanisms for the enhanced dislocation activity in the nanocomposites are discussed.

KW - residual stress

KW - transmission electron microscopy (TEM)

KW - dislocations

KW - ceramics

KW - microstructure

U2 - 10.1016/S1359-6454(00)00333-5

DO - 10.1016/S1359-6454(00)00333-5

M3 - Article

SN - 1873-2453

VL - 49

SP - 507

EP - 517

JO - Acta Materialia

JF - Acta Materialia

IS - 3

ER -

Residual stress and subsurface damage in machined alumina and alumina/silicon carbide nanocomposite ceramics

Abstract

Keywords

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