Precipitation in a 2xxx series Al-Cu-Mg-Zr alloy fabricated by laser powder bed fusion

[Display omitted] •Precipitation-strengthened 2xxx Al alloys but show solidification cracking issues during AM•Equiaxed, crack-free microstructures achieved in a model AlCuMg alloy by adding Zr.•Strengthening by S-Al2CuMg and L12-Al3Zr precipitates after three-step heat treatment.•Strengthening by S...

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Bibliographic Details
Published in:Materials & design 2021-12, Vol.211, p.110131, Article 110131
Main Authors: Schuster, Marvin, De Luca, Anthony, Mathur, Aditi, Hosseini, Ehsan, Leinenbach, Christian
Format: Article
Language:English
Subjects:
2xxx Al alloy
Additive manufacturing
Heat treatment
Laser powder bed fusion
Precipitation
Selective Laser Melting
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Summary:[Display omitted] •Precipitation-strengthened 2xxx Al alloys but show solidification cracking issues during AM•Equiaxed, crack-free microstructures achieved in a model AlCuMg alloy by adding Zr.•Strengthening by S-Al2CuMg and L12-Al3Zr precipitates after three-step heat treatment.•Strengthening by S- and L12-phase characterized by microhardness and compression testing. The processing of conventional alloys by laser-based additive manufacturing can be challenging, particularly for alloys prone to hot cracking. However, additive manufacturing offers the possibility to produce novel alloys with improved properties, which cannot be achieved by other processing methods. Although several studies have demonstrated the positive influence of Zr addition on crack prevention of Al alloys tailored to additive manufacturing, its influence on the formation of strengthening precipitates in 2xxx alloys, remains largely unexplored. This work investigates the microstructure of a Zr-modified 2xxx AlCuMgZr alloy fabricated by laser powder bed fusion, with a particular emphasis on the precipitation of phases induced by the post-processing heat treatment, and their effects on mechanical properties. The Zr addition successfully allows the consolidation of crack-free, dense material (>99.5%). The microstructure is characterized by fine, equiaxed grains (0.5–3 μm) which result from Al3Zr-induced grain nucleation, with the grain boundary covered in eutectic S-Al2CuMg. After optimized three-step heat treatment, nm-sized L12-Al3Zr as well as S-Al2CuMg rods strengthen the alloy, and lead to microhardness, young's modulus and yield strength of ∼1410 MPa, ∼82 GPa and ∼340 MPa, respectively. The results provide a basis for the understanding and further development of 2xxx alloys tailored to additive manufacturing.
ISSN:0264-1275
1873-4197
DOI:10.1016/j.matdes.2021.110131