Your search keyword '"Cu-Fe alloys"' showing total 3 results

1. Phase Transitions of Cu and Fe at Multiscales in an Additively Manufactured Cu–Fe Alloy under High-Pressure.

Author

Chatterjee, Arya, Popov, Dmitry, Velisavljevic, Nenad, and Misra, Amit

Abstract

A state of the art, custom-built direct-metal deposition (DMD)-based additive manufacturing (AM) system at the University of Michigan was used to manufacture 50Cu–50Fe alloy with tailored properties for use in high strain/deformation environments. Subsequently, we performed preliminary high-pressure compression experiments to investigate the structural stability and deformation of this material. Our work shows that the alpha (BCC) phase of Fe is stable up to ~16 GPa before reversibly transforming to HCP, which is at least a few GPa higher than pure bulk Fe material. Furthermore, we observed evidence of a transition of Cu nano-precipitates in Fe from the well-known FCC structure to a metastable BCC phase, which has only been predicted via density functional calculations. Finally, the metastable FCC Fe nano-precipitates within the Cu grains show a modulated nano-twinned structure induced by high-pressure deformation. The results from this work demonstrate the opportunity in AM application for tailored functional materials and extreme stress/deformation applications. [ABSTRACT FROM AUTHOR]

Published

2022

2. Phase Transitions of Cu and Fe at Multiscales in an Additively Manufactured Cu–Fe Alloy under High-Pressure

Author

Arya Chatterjee, Dmitry Popov, Nenad Velisavljevic, and Amit Misra

Subjects

Cu–Fe alloys, additive manufacturing, hierarchical microstructure, phase transformation, Cu and Fe precipitates, Chemistry, QD1-999

Abstract

A state of the art, custom-built direct-metal deposition (DMD)-based additive manufacturing (AM) system at the University of Michigan was used to manufacture 50Cu–50Fe alloy with tailored properties for use in high strain/deformation environments. Subsequently, we performed preliminary high-pressure compression experiments to investigate the structural stability and deformation of this material. Our work shows that the alpha (BCC) phase of Fe is stable up to ~16 GPa before reversibly transforming to HCP, which is at least a few GPa higher than pure bulk Fe material. Furthermore, we observed evidence of a transition of Cu nano-precipitates in Fe from the well-known FCC structure to a metastable BCC phase, which has only been predicted via density functional calculations. Finally, the metastable FCC Fe nano-precipitates within the Cu grains show a modulated nano-twinned structure induced by high-pressure deformation. The results from this work demonstrate the opportunity in AM application for tailored functional materials and extreme stress/deformation applications.

Published

2022

3. Hierarchical microstructures and deformation behavior of laser direct-metal-deposited Cu–Fe alloys.

Author

Chatterjee, Arya, Sprague, Ethan, Mazumder, Jyoti, and Misra, Amit

Subjects

*LASER deposition, *ALLOYS, *STRAIN hardening, *MICROSTRUCTURE, *GRAIN refinement, *LASERS, *MAGNESIUM alloys, *COBALT nickel alloys

Abstract

Cu25Fe75 and Cu50Fe50 (nominal composition, at. %) alloys were fabricated using laser direct metal deposition (DMD) based additive manufacturing technique. These alloys exhibit hierarchical microstructures with bi-phasic Cu and Fe dendrites that contain nanoscale precipitates of varying sizes and structures. In the Cu25Fe75 alloy, Fe dendrites contained nanoscale, coherent, metastable BCC Cu and semi-coherent FCC Cu precipitates while the Cu matrix had nanoscale, coherent, metastable FCC Fe precipitates. In the Cu50Fe50 alloy, Fe dendrites only contained nanoscale semi-coherent FCC Cu precipitates while the Cu matrix had nanoscale coherent metastable FCC Fe precipitates. Both alloys exhibited enhanced flow strengths in the range of 750–980 MPa and significant plasticity, in compression. The Cu25Fe75 alloy had lower yield strength than Cu50Fe50 alloy but higher maximum compressive strength due to higher strain hardening resulting from slightly coarser dendrites with hierarchy of nanoscale precipitation. • Laser direct-metal-deposition based additive manufacturing is used to make Cu–Fe alloys. • Alloys show formation of hierarchical microstructure in Cu matrix and Fe dendrites. • Metastable BCC and FCC Cu precipitates are present in Fe dendrites. • Only coherent metastable FCC Fe precipitates are visible in Cu matrix. • Alloy with more Cu content shows grain refinement and higher yield strength. [ABSTRACT FROM AUTHOR]

Published

2021