Summary
Combining strength and formability, metals are indispensable for modern life. Their properties firmly depend on processing, typically involving a series of plastic deformation steps that introduce defects deep below the surface. Our current understanding of the evolution of defect structures is phenomenological, and strongly limited by characterization tools being either limited to surfaces or not available at deformation levels relevant for metal processing.
D-REX strives to radically improve our understanding of structure-property relations in plastic deformation and thermal annealing of metals by visualising and quantifying the structural dynamics in 3D with 100nm resolution – within bulk metals. This will be achieved by developing a unique multi-scale full-field X-ray diffraction microscope enabling time-resolved 3D strain and orientation mapping. Using pink beam diffraction imaging, the time resolution of the microscope is expected to be ~100× better than the existing diffraction imaging methods. The unique experimental results will be used to guide and validate crystal plasticity and phase field models.
D-REX opens a new way to address the unresolved questions of how metals get stronger during deformation and how this affects the annealing processes. For the first time, industrially-relevant deformation levels can be quantitatively and systematically mapped in real-life conditions. This will not only lead to a new scientific understanding, but also provide unprecedented access to critical material parameters from the bulk that will refine material models. More broadly, the novel multi-scale methodology and systematic approach of D-REX will be a game-changer for studies of many hierarchically-ordered crystalline materials.
D-REX strives to radically improve our understanding of structure-property relations in plastic deformation and thermal annealing of metals by visualising and quantifying the structural dynamics in 3D with 100nm resolution – within bulk metals. This will be achieved by developing a unique multi-scale full-field X-ray diffraction microscope enabling time-resolved 3D strain and orientation mapping. Using pink beam diffraction imaging, the time resolution of the microscope is expected to be ~100× better than the existing diffraction imaging methods. The unique experimental results will be used to guide and validate crystal plasticity and phase field models.
D-REX opens a new way to address the unresolved questions of how metals get stronger during deformation and how this affects the annealing processes. For the first time, industrially-relevant deformation levels can be quantitatively and systematically mapped in real-life conditions. This will not only lead to a new scientific understanding, but also provide unprecedented access to critical material parameters from the bulk that will refine material models. More broadly, the novel multi-scale methodology and systematic approach of D-REX will be a game-changer for studies of many hierarchically-ordered crystalline materials.
Unfold all
/
Fold all
More information & hyperlinks
| Web resources: | https://cordis.europa.eu/project/id/101116911 |
| Start date: | 01-01-2024 |
| End date: | 31-12-2028 |
| Total budget - Public funding: | 1 500 000,00 Euro - 1 500 000,00 Euro |
Cordis data
Original description
Combining strength and formability, metals are indispensable for modern life. Their properties firmly depend on processing, typically involving a series of plastic deformation steps that introduce defects deep below the surface. Our current understanding of the evolution of defect structures is phenomenological, and strongly limited by characterization tools being either limited to surfaces or not available at deformation levels relevant for metal processing.D-REX strives to radically improve our understanding of structure-property relations in plastic deformation and thermal annealing of metals by visualising and quantifying the structural dynamics in 3D with 100nm resolution – within bulk metals. This will be achieved by developing a unique multi-scale full-field X-ray diffraction microscope enabling time-resolved 3D strain and orientation mapping. Using pink beam diffraction imaging, the time resolution of the microscope is expected to be ~100× better than the existing diffraction imaging methods. The unique experimental results will be used to guide and validate crystal plasticity and phase field models.
D-REX opens a new way to address the unresolved questions of how metals get stronger during deformation and how this affects the annealing processes. For the first time, industrially-relevant deformation levels can be quantitatively and systematically mapped in real-life conditions. This will not only lead to a new scientific understanding, but also provide unprecedented access to critical material parameters from the bulk that will refine material models. More broadly, the novel multi-scale methodology and systematic approach of D-REX will be a game-changer for studies of many hierarchically-ordered crystalline materials.
Status
SIGNEDCall topic
ERC-2023-STGUpdate Date
12-03-2024
Images
No images available.
Geographical location(s)
