Deformation microstructure under nanoindentations in Cu using 3D x-ray structural microscopy

Wenge Yang; B.C. Larson; G.M. Pharr; G.E. Ice; J.G. Swadener; J.D. Budai; J.Z. Tischler; Wenjun Liu

doi:10.1557/PROC-750-Y8.26

Deformation microstructure under nanoindentations in Cu using 3D x-ray structural microscopy

Wenge Yang, B.C. Larson, G.M. Pharr, G.E. Ice, J.G. Swadener, J.D. Budai, J.Z. Tischler, Wenjun Liu

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

Abstract

We have used a recently developed x-ray structural microscopy technique to make nondestructive, submicron-resolution measurements of the deformation microstructure below a 100mN maximum load Berkovich nanoindent in single crystal Cu. Direct observations of plastic deformation under the indent were obtained using a ~0.5 µm polychromatic microbeam and diffracted beam depth profiling to make micron-resolution spatially-resolved x-ray Laue diffraction measurements. The local lattice rotations underneath the nanoindent were found to be heterogeneous in nature as revealed by geometrically necessary dislocation (GND) densities determined for positions along lines beneath a flat indent face and under the sharp Berkovich indent blade edges. Measurements of the local rotation-axes and misorientation-angles along these lines are discussed in terms of crystallographic slip systems.

Original language	English
Pages (from-to)	113-118
Number of pages	6
Journal	Materials Research Society Symposium Proceedings
Volume	750
DOIs	https://doi.org/10.1557/PROC-750-Y8.26
Publication status	Published - Jan 2002

Keywords

Deformation
Microstructure
Nanoindentations in Cu
3D X-Ray
Structural
Microscopy

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10.1557/PROC-750-Y8.26

Cite this

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title = "Deformation microstructure under nanoindentations in Cu using 3D x-ray structural microscopy",

abstract = "We have used a recently developed x-ray structural microscopy technique to make nondestructive, submicron-resolution measurements of the deformation microstructure below a 100mN maximum load Berkovich nanoindent in single crystal Cu. Direct observations of plastic deformation under the indent were obtained using a ~0.5 µm polychromatic microbeam and diffracted beam depth profiling to make micron-resolution spatially-resolved x-ray Laue diffraction measurements. The local lattice rotations underneath the nanoindent were found to be heterogeneous in nature as revealed by geometrically necessary dislocation (GND) densities determined for positions along lines beneath a flat indent face and under the sharp Berkovich indent blade edges. Measurements of the local rotation-axes and misorientation-angles along these lines are discussed in terms of crystallographic slip systems.",

keywords = "Deformation, Microstructure, Nanoindentations in Cu, 3D X-Ray, Structural, Microscopy",

author = "Wenge Yang and B.C. Larson and G.M. Pharr and G.E. Ice and J.G. Swadener and J.D. Budai and J.Z. Tischler and Wenjun Liu",

year = "2002",

month = jan,

doi = "10.1557/PROC-750-Y8.26",

language = "English",

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pages = "113--118",

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T1 - Deformation microstructure under nanoindentations in Cu using 3D x-ray structural microscopy

AU - Yang, Wenge

AU - Larson, B.C.

AU - Pharr, G.M.

AU - Ice, G.E.

AU - Swadener, J.G.

AU - Budai, J.D.

AU - Tischler, J.Z.

AU - Liu, Wenjun

PY - 2002/1

Y1 - 2002/1

N2 - We have used a recently developed x-ray structural microscopy technique to make nondestructive, submicron-resolution measurements of the deformation microstructure below a 100mN maximum load Berkovich nanoindent in single crystal Cu. Direct observations of plastic deformation under the indent were obtained using a ~0.5 µm polychromatic microbeam and diffracted beam depth profiling to make micron-resolution spatially-resolved x-ray Laue diffraction measurements. The local lattice rotations underneath the nanoindent were found to be heterogeneous in nature as revealed by geometrically necessary dislocation (GND) densities determined for positions along lines beneath a flat indent face and under the sharp Berkovich indent blade edges. Measurements of the local rotation-axes and misorientation-angles along these lines are discussed in terms of crystallographic slip systems.

AB - We have used a recently developed x-ray structural microscopy technique to make nondestructive, submicron-resolution measurements of the deformation microstructure below a 100mN maximum load Berkovich nanoindent in single crystal Cu. Direct observations of plastic deformation under the indent were obtained using a ~0.5 µm polychromatic microbeam and diffracted beam depth profiling to make micron-resolution spatially-resolved x-ray Laue diffraction measurements. The local lattice rotations underneath the nanoindent were found to be heterogeneous in nature as revealed by geometrically necessary dislocation (GND) densities determined for positions along lines beneath a flat indent face and under the sharp Berkovich indent blade edges. Measurements of the local rotation-axes and misorientation-angles along these lines are discussed in terms of crystallographic slip systems.

KW - Deformation

KW - Microstructure

KW - Nanoindentations in Cu

KW - 3D X-Ray

KW - Structural

KW - Microscopy

UR - http://www.scopus.com/inward/record.url?scp=0042968723&partnerID=8YFLogxK

UR - http://journals.cambridge.org/action/displayAbstract?fromPage=online&aid=8067689&fileId=S1946427400158816

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DO - 10.1557/PROC-750-Y8.26

M3 - Article

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VL - 750

SP - 113

EP - 118

JO - Materials Research Society Symposium Proceedings

JF - Materials Research Society Symposium Proceedings

ER -

Deformation microstructure under nanoindentations in Cu using 3D x-ray structural microscopy

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Keywords

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