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| Main Authors: | , , , , , , , , |
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| Format: | Preprint |
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2026
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| Subjects: | |
| Online Access: | https://arxiv.org/abs/2602.18954 |
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| _version_ | 1866915811120119808 |
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| author | Ryou, KenHee Zhang, Yaozhong Ball, James A. D. Rubio-Ejchel, Dan Jobes, Dillon Ibrahim, Buhari Romain, Charles Proudhon, Henry Gordon, Jerard V. |
| author_facet | Ryou, KenHee Zhang, Yaozhong Ball, James A. D. Rubio-Ejchel, Dan Jobes, Dillon Ibrahim, Buhari Romain, Charles Proudhon, Henry Gordon, Jerard V. |
| contents | Laser powder bed fusion (L-PBF) additive manufacturing offers a remarkable balance of strength and ductility across many structural alloys. However, L-PBF alloys often display much lower fracture toughness, in some cases up to 70% below conventionally wrought counterparts. The reasons for this toughness paradox have remained elusive, since conventional tools cannot directly visualize sub-surface microscale deformation processes that govern crack growth. Here we apply scanning 3D X-ray diffraction and phase contrast tomography to simultaneously capture microstructural evolution with 1 micron resolution near an advancing crack tip, utilizing 316L stainless steel as a model system. We demonstrate that the toughness paradox is not solely a consequence of extrinsic processing defects or residual stresses, but rather an intrinsic failure to relax crack-tip stresses via plasticity. While wrought material facilitates stable crack-tip blunting through localized dislocation accumulation, the L-PBF material undergoes premature work-hardening saturation that triggers extreme stress partitioning and high stress triaxiality. This results in a transition from ductile blunting to a sharp, unstable fracture mode. These findings identify work-hardening exhaustion as a systemic vulnerability inherent to L-PBF microstructures, where the exceptional initial dislocation density required for high yield strength acts as a saturation ceiling for damage tolerance. This work provides a physical basis for adapting damage models to L-PBF metals and challenges the assumption that high tensile ductility guarantees fracture resistance in rapidly solidified components. |
| format | Preprint |
| id |
arxiv_https___arxiv_org_abs_2602_18954 |
| institution | arXiv |
| publishDate | 2026 |
| record_format | arxiv |
| spellingShingle | Work-hardening exhaustion as the origin of low toughness in L-PBF alloys: A case study on the role of intrinsic vs. extrinsic defects in SS316L Ryou, KenHee Zhang, Yaozhong Ball, James A. D. Rubio-Ejchel, Dan Jobes, Dillon Ibrahim, Buhari Romain, Charles Proudhon, Henry Gordon, Jerard V. Materials Science Laser powder bed fusion (L-PBF) additive manufacturing offers a remarkable balance of strength and ductility across many structural alloys. However, L-PBF alloys often display much lower fracture toughness, in some cases up to 70% below conventionally wrought counterparts. The reasons for this toughness paradox have remained elusive, since conventional tools cannot directly visualize sub-surface microscale deformation processes that govern crack growth. Here we apply scanning 3D X-ray diffraction and phase contrast tomography to simultaneously capture microstructural evolution with 1 micron resolution near an advancing crack tip, utilizing 316L stainless steel as a model system. We demonstrate that the toughness paradox is not solely a consequence of extrinsic processing defects or residual stresses, but rather an intrinsic failure to relax crack-tip stresses via plasticity. While wrought material facilitates stable crack-tip blunting through localized dislocation accumulation, the L-PBF material undergoes premature work-hardening saturation that triggers extreme stress partitioning and high stress triaxiality. This results in a transition from ductile blunting to a sharp, unstable fracture mode. These findings identify work-hardening exhaustion as a systemic vulnerability inherent to L-PBF microstructures, where the exceptional initial dislocation density required for high yield strength acts as a saturation ceiling for damage tolerance. This work provides a physical basis for adapting damage models to L-PBF metals and challenges the assumption that high tensile ductility guarantees fracture resistance in rapidly solidified components. |
| title | Work-hardening exhaustion as the origin of low toughness in L-PBF alloys: A case study on the role of intrinsic vs. extrinsic defects in SS316L |
| topic | Materials Science |
| url | https://arxiv.org/abs/2602.18954 |