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Deposition and nanoindentation study of a novel TiNi/Ag bi-layer shape memory film

Xiaoxue Huang, Hao Li, Changwen Jin, Bowen Huang, Xinhang Li, Yiping Zheng, Xianglong Meng, Zhiyong Gao

2024Journal of Materials Research and Technology9 citationsDOIOpen Access PDF

Abstract

Compositions, surface morphologies and mechanical properties of a novel designed TiNi/Ag bi-layer film grown by DC magnetron sputtering at various processes have been investigated. Ar pressure and sputtering power had significant effects on quality and composition of TiNi/Ag bi-layer films. The TiNi/Ag bi-layer film processed by sputtering under high Ar pressure (0.36 Pa) was porous, while better density films can only be obtained at low pressure (0.12 Pa). The composition of TiNi/Ag bi-layer films can be adjusted by sputtering power. The load-displacement curves show the multiple “pop-ins”along nanoindentation loading, as indentation depth does not exceed the pure Ag film thickness ( ∼ 340 nm). At the maximum loading of 140 mN, martensitic transformation induced by nanoindentation in TiNi/Ag bi-layer films was not found, and depth recovery ratio was 39%. Moreover, based on the load displacement curve analysis, the hardness and elastic modulus values of TiNi/Ag bi-layer films were 4 ± 0.2 Gpa and 79 ± 2 Gpa, respectively. Comparing with martensitic phase of single-layer TiNi thin films at room temperature, the coexistence of parent phase and martensitic phase of TiNi/Ag bi-layer films were mainly due to strong confinement effect of Ag layer deposition on TiNi thin film. The residual stress calculated by using conventional sin2ψ method was around -0.458 GPa. The present study provided an important theoretical basis for the preparation of TiNi/Ag bi-layer film with higher quality and performance.

Topics & Concepts

NanoindentationMaterials scienceLayer (electronics)Deposition (geology)Shape-memory alloyMetallurgyComposite materialGeologyPaleontologySedimentShape Memory Alloy TransformationsMetal and Thin Film MechanicsFerroelectric and Piezoelectric Materials