TY - JOUR

T1 - Evaluation of Interface and Residual Strain of NiTi Layer Deposited on NiTiX Substrate by Laser Powder Bed Fusion

AU - Memarian, Mahshid

AU - Mohri, Maryam

AU - Golrang, Mahbod

AU - Leinenbach, Christian

AU - Ferretto, Irene

AU - Ghafoori, Elyas

AU - Nili-Ahmadabadi, Mahmoud

N1 - Funding Information: This work in part was supported by Iran National Science Foundation (INSF) (grant no: 4015297) which is acknowledged by Mahmoud Nili-Ahmadabadi. Open access funding provided by ETH-Bereich Forschungsanstalten.

PY - 2024/4/11

Y1 - 2024/4/11

N2 - This study investigates the microstructure and properties of functionally graded NiTi alloy bilayers. The NiTi layer is printed by laser powder bed fusion on a NiTiX (where X is Hf or Cu) substrate prepared by vacuum arc remelting. Specimens produced with different thicknesses of layers, but constant thickness ratio, are examined by optical and scanning electron microscopy prior to and postannealing process at 1000 °C for 16 h. Scanning electron microscopy– energy-dispersive X-ray spectroscopy and transmission electron microscopy studies reveal the presence of Ti2Ni and Ni4Ti3 precipitates in the as-printed NiTi/NiTiCu samples and Ti2Ni type precipitates in as-printed NiTi/NiTiHf. Digital image correlation quantifies residual strain in the as-printed bilayer and enables strain relief to be monitored during heating. It has been shown that microcracks occurring along interfacial zones during the laser powder bed fusion are diminished after annealing heat treatment. The microcrack closure occurs by diffusion of third elements to the open microcracks, leading to precipitation and accumulation of third elements in the interfaces. Eventually, the as-printed NiTi/NiTiCu sample displays two-way shape memory effects with about 24.5% shape recovery. This work enhances understanding of controlling fabrication to yield tailored properties in additively manufactured functionally graded NiTi-based materials.

AB - This study investigates the microstructure and properties of functionally graded NiTi alloy bilayers. The NiTi layer is printed by laser powder bed fusion on a NiTiX (where X is Hf or Cu) substrate prepared by vacuum arc remelting. Specimens produced with different thicknesses of layers, but constant thickness ratio, are examined by optical and scanning electron microscopy prior to and postannealing process at 1000 °C for 16 h. Scanning electron microscopy– energy-dispersive X-ray spectroscopy and transmission electron microscopy studies reveal the presence of Ti2Ni and Ni4Ti3 precipitates in the as-printed NiTi/NiTiCu samples and Ti2Ni type precipitates in as-printed NiTi/NiTiHf. Digital image correlation quantifies residual strain in the as-printed bilayer and enables strain relief to be monitored during heating. It has been shown that microcracks occurring along interfacial zones during the laser powder bed fusion are diminished after annealing heat treatment. The microcrack closure occurs by diffusion of third elements to the open microcracks, leading to precipitation and accumulation of third elements in the interfaces. Eventually, the as-printed NiTi/NiTiCu sample displays two-way shape memory effects with about 24.5% shape recovery. This work enhances understanding of controlling fabrication to yield tailored properties in additively manufactured functionally graded NiTi-based materials.

KW - additive manufacturing

KW - characterizations

KW - interfaces

KW - shape memory alloys

KW - thermal analyses

KW - two-way shape memory effects

UR - http://www.scopus.com/inward/record.url?scp=85190782650&partnerID=8YFLogxK

U2 - 10.1002/adem.202400002

DO - 10.1002/adem.202400002

M3 - Article

AN - SCOPUS:85190782650

JO - Advanced engineering materials

JF - Advanced engineering materials

SN - 1438-1656

ER -