Abstract
Elastoplastic phenomena, such as plastic deformation and failure, are multi-scale, deformation-path-dependent, and mechanical-field-sensitive problems associated with metals. Accordingly, visualization of the microstructural deformation path under a specific mechanical field is challenging for the elucidation of elastoplastic phenomena mechanisms. To overcome this problem, a dislocation-resolved in-situ technique for deformation under mechanically controllable conditions is required. Thus, we attempted to apply electron channeling contrast imaging (ECCI) under tensile loading, which enabled the detection of lattice defect motions and the evolution of elastic strain fields in bulk specimens. Here, we presented the suitability of ECCI as an in-situ technique with dislocation-detectable spatial resolution. In particular, the following ECCI-visualized plasticity-related phenomena were observed: (1) pre-deformation-induced residual stress and its disappearance via subsequent reloading, (2) heterogeneous dislocation motion during plastic relaxation, and (3) planar surface relief formation via loading to a higher stress.
Highlights
Electron channeling contrast imaging (ECCI) enables visualization of dislocations[10,11,12,13], stacking faults[6,11,12,14], twins[11,12,15,16], and elastic strain fields using a field-emission scanning electron microscope
In this study, we investigated the suitability of electron channeling contrast imaging (ECCI) as an in-situ characterization technique, while presenting its applicability for in-situ observation of a bulk metallic specimen under tensile loading
Afterwards, the pre-deformed specimen with the tensile stage was set into the field emission scanning electron microscope for performing the in-situ ECCI observations
Summary
Electron channeling contrast imaging (ECCI) enables visualization of dislocations[10,11,12,13], stacking faults[6,11,12,14], twins[11,12,15,16], and elastic strain fields using a field-emission scanning electron microscope. Electron channeling contrast images of the 2% pre-deformed and mechanically polished specimen (a) under an unloading condition and (b) after reloading to 199 MPa and displacement holding for 8 min. This image was taken after the sample was submitted to pre-deformation of 2% tensile strain (corresponding to 246 MPa of external stress), followed by mechanical polishing.
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