Synchrotron X-ray characterization of crack strain fields in polygranular graphite

SM Barhli; L Saucedo-Mora; MSL Jordan; AF Cinar; C Reinhard; M Mostafavi; TJ Marrow

doi:10.1016/j.carbon.2017.08.075

Synchrotron X-ray characterization of crack strain fields in polygranular graphite

SM Barhli, L Saucedo-Mora, MSL Jordan, AF Cinar, C Reinhard, M Mostafavi, TJ Marrow

Diamond Light Source Ltd

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

Abstract

The strain field of a crack in polygranular isotropic nuclear graphite, a quasi-brittle material, has been studied during stable fracture propagation. Synchrotron X-ray computed tomography and strain mapping by diffraction were combined with digital volume correlation and phase congruency image analysis to extract the full field displacements and elastic crystal strains. The measured displacement fields have been analysed using a Finite Element method to extract the elastic strain energy release rate as a J-integral. Non-linear properties described the effect of microcracking on the elastic modulus in the fracture process zone. The analysis was verified by the good agreement of the predicted and measured elastic strain fields when using the non-linear model. The intrinsic critical elastic strain energy release rate for mode I crack propagation is approximately 200 J m⁻².

Original language	English
Pages (from-to)	357-371
Number of pages	15
Journal	Carbon
Volume	124
Early online date	3 Sept 2017
DOIs	https://doi.org/10.1016/j.carbon.2017.08.075
Publication status	Published - Nov 2017
Externally published	Yes

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abstract = "The strain field of a crack in polygranular isotropic nuclear graphite, a quasi-brittle material, has been studied during stable fracture propagation. Synchrotron X-ray computed tomography and strain mapping by diffraction were combined with digital volume correlation and phase congruency image analysis to extract the full field displacements and elastic crystal strains. The measured displacement fields have been analysed using a Finite Element method to extract the elastic strain energy release rate as a J-integral. Non-linear properties described the effect of microcracking on the elastic modulus in the fracture process zone. The analysis was verified by the good agreement of the predicted and measured elastic strain fields when using the non-linear model. The intrinsic critical elastic strain energy release rate for mode I crack propagation is approximately 200 J m−2.",

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AU - Barhli, SM

AU - Saucedo-Mora, L

AU - Jordan, MSL

AU - Cinar, AF

AU - Reinhard, C

AU - Mostafavi, M

AU - Marrow, TJ

PY - 2017/11

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N2 - The strain field of a crack in polygranular isotropic nuclear graphite, a quasi-brittle material, has been studied during stable fracture propagation. Synchrotron X-ray computed tomography and strain mapping by diffraction were combined with digital volume correlation and phase congruency image analysis to extract the full field displacements and elastic crystal strains. The measured displacement fields have been analysed using a Finite Element method to extract the elastic strain energy release rate as a J-integral. Non-linear properties described the effect of microcracking on the elastic modulus in the fracture process zone. The analysis was verified by the good agreement of the predicted and measured elastic strain fields when using the non-linear model. The intrinsic critical elastic strain energy release rate for mode I crack propagation is approximately 200 J m−2.

AB - The strain field of a crack in polygranular isotropic nuclear graphite, a quasi-brittle material, has been studied during stable fracture propagation. Synchrotron X-ray computed tomography and strain mapping by diffraction were combined with digital volume correlation and phase congruency image analysis to extract the full field displacements and elastic crystal strains. The measured displacement fields have been analysed using a Finite Element method to extract the elastic strain energy release rate as a J-integral. Non-linear properties described the effect of microcracking on the elastic modulus in the fracture process zone. The analysis was verified by the good agreement of the predicted and measured elastic strain fields when using the non-linear model. The intrinsic critical elastic strain energy release rate for mode I crack propagation is approximately 200 J m−2.

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JF - Carbon

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Synchrotron X-ray characterization of crack strain fields in polygranular graphite

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