Nanoindentation of a Pseudoelastic NiTiFe Shape Memory Alloy

## Abstract A thermodynamic model describing pseudoelasticity is proposed. The kinematics are based on a self‐consistent Eulerian theory of finite deformations using the logarithmic rate. The thermomechanical state of the material is described by means of the mass fraction of martensite as internal

This paper examines the e!ectiveness of pseudoelastic shape memory alloy (SMA) wires for passive damping of #exural vibrations of a clamped}free beam with a tip mass. A "nite-element model of the system is developed and validated with experimental results. The SMA behavior is modelled using amplitud

## Abstract Pseudoelastic NiTi‐ shape memory alloys (SMAs) provide a high damping capacity and can be used in order to achieve a reduction of peak loads being caused by unexpected shock loading. These “pseudoelastic” properties are related to the formation of martensite M from austenite A, which ha

## Abstract This paper takes into account the localized deformation behaviour of a pseudoelastic NiTi shape memory alloy with finite element method. A three‐dimensional micromechanical model has been developed, in which the difference between the elastic properties of austenite and martensite is co

## Abstract For Abstract see ChemInform Abstract in Full Text.

## Abstract An isothermal finite element method (FEM) model has been applied to study the behavior of two kinds of shape memory alloy (SMA) composites. For SMA‐fiber reinforced normal metal composites, the FEM analysis shows that the mechanical behavior of the composites depends on the SMA volume f