Influence of Structural Porosity and Martensite Evolution on Mechanical Characteristics of Nitinol via In-Silico Finite Element Approach

Abstract: Nitinol (NiTi) alloys are gaining extensive attention due to their excellent mechanical, superelasticity, and biocompatibility properties. It is difficult to model the complex mechanical behavior of NiTi alloys due to the solid-state diffusionless phase transformations, and the differing elasticity and plasticity presenting from these two phases. In this work, an Auricchio finite element (FE) model was used to model the mechanical behavior of superelastic NiTi and was validated with experimental data from lite… Show more

“…Super elasticity refers to the alloy's ability to recover large amounts of strain without the need for heating, while the shape memory effect allows the alloy to return to its original shape after being mechanically deformed and heated above its transformation temperature. 29 These properties make nitinol a suitable material for use in bone staple fixation, as it can provide compressive forces at the site of deployment and improve the stability and performance of the staples. The nitinol alloy also has some disadvantages related to its fatigue life.…”

Comparative Finite Element (FE) Analysis of the Mechanical Behavior in an Innovative Nitinol Staple for Arthrodesis in Distal Interphalangeal Joint

“…Super elasticity refers to the alloy's ability to recover large amounts of strain without the need for heating, while the shape memory effect allows the alloy to return to its original shape after being mechanically deformed and heated above its transformation temperature. 29 These properties make nitinol a suitable material for use in bone staple fixation, as it can provide compressive forces at the site of deployment and improve the stability and performance of the staples. The nitinol alloy also has some disadvantages related to its fatigue life.…”

Comparative Finite Element (FE) Analysis of the Mechanical Behavior in an Innovative Nitinol Staple for Arthrodesis in Distal Interphalangeal Joint

“…The austenite phase (high temperature phase) of the SMAs is hard and stiff. [122] When cooled down below the phasetransition temperature, the crystalline structure of the SMAs will change to martensite phase (low temperature phase), which is soft and deformable. [123] Under the applied stress, the SMAs can be deformed into a specific shape by reorienting and detwinning the lattice structure.…”

Conducting Polymer-based Biohybrid Materials : Towards Microphysiological Chips and Soft Actuators for Bone Tissue Engineering

Steady-state and transient mechanical response analysis of superelastic nitinol lattice structures prior to additive manufacturing: An in-silico study