Assessing the precision of strain measurements using electron backscatter diffraction – Part 2: Experimental demonstration

The residual impression after performing a microhardness indent in silicon has been mapped with high resolution EBSD to reveal residual elastic strain and lattice rotation fields. Mapping of the same area has been performed with variable pattern binning and exposure times to reveal the qualitative a...

Full description

Saved in:
Bibliographic Details
Published in:Ultramicroscopy 2013-12, Vol.135, p.136-141
Main Authors: Britton, T.B., Jiang, J., Clough, R., Tarleton, E., Kirkland, A.I., Wilkinson, A.J.
Format: Article
Language:English
Subjects:
Assessments
Cross correlation
Damage
EBSD
Electron back scatter diffraction
Exposure
Finite element analysis
Fracture mechanics
Hardening
Indentation
Silicon
Strain
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:The residual impression after performing a microhardness indent in silicon has been mapped with high resolution EBSD to reveal residual elastic strain and lattice rotation fields. Mapping of the same area has been performed with variable pattern binning and exposure times to reveal the qualitative and quantitative differences resulting from reducing the pattern size and exposure time. Two dimension ‘image’ plots of these fields indicate that qualitative assessment of the shape and size of the fields can be performed with as much as 4×4 binning. However, quantitative assessment using line scans reveals that the smoothest profile can be obtained using minimal pattern binning and long exposure times. To compare and contrast with these experimental maps, finite element analysis has been performed using a continuum damage-plasticity material law which has been independently calibrated to Si [9]. The constitutive law incorporates isotropic hardening in compression, and isotropic hardening and damage in tension. To accurately capture the localised damage which develops during indentation via the nucleation and propagation of cracks around the indentation site cohesive elements were assigned along the interfaces between the planes which experience the maximum traction. The residual strain state around the indenter and the size of the cracks agree very well with the experimentally measured value. •Similar deformation fields around a microhardness indent have been characterised with HR-EBSD and simulated with a finite element model.•Qualitative assessment of the stress field can be performed with significant EBSD pattern binning (i.e. faster capture of maps).•Quantitative assessment of the stress fields benefits significantly from increased exposure times and minimal binning.
ISSN:0304-3991
1879-2723
DOI:10.1016/j.ultramic.2013.08.006