Constitutive modelling and numerical simulation of multivariant phase transformation in superelastic shape‐memory alloys

Jung, Youngjean; Papadopoulos, Panayiotis; Ritchie, Robert O.

doi:10.1002/nme.940

Cited by 50 publications

(62 citation statements)

References 23 publications

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“…These assumptions are in line with the work of Huang, Gao, and Brinson [47]. Furthermore, the total number of martensitic variants depends on the crystalline structure, Jung, Papadopoulos, and Ritchie [48], and it is reported in Brinson, Lammering, and Schmidt [22] that the active variants in each grain are the same in each load-unload cycle according to the type of alloy. This has been illustrated in the micrograph of activated variants at 2% strain in one set of grains at different cycle numbers for NiTi alloy, [22].…”

Section: Presumptions For Polycrystalssupporting

confidence: 69%

“…Lu and Weng [56,57] proposed a self-consistent model where the variants are interacting within crystals. The model proposed by Jung et al [48] considers the coupling between variants and neglects the interaction between grains. In the presented polycrystalline model too, the interaction between the variants (of equivalent monocrystal) is considered via quasi-convex relaxation which is intimately connected to the notion of homogenization of optimal microstructure (at minimum energy).…”

Section: State Of the Art Of Engineering Theories And Computational Mmentioning

confidence: 99%

“…(47) - (50); n is the total number of phases, and m is the number of constraints for the active set. The global unknowns are stored in the vector X := {f , γ B , Δλ, δ} and the global residuals in the vector R := {(47), (48), (49), (50)}. The iteration tangent matrix reads (see also [38])…”

Section: Time Integration Of Constitutive Equations In Each Materials mentioning

confidence: 99%

“…3. Based on these kinematic assumptions, theories and computations of monocrystalline PTs have been treated in, e.g., [38,41,46,76,77], and polycrystalline research results can be found in, e.g., [22,40,47,48,60,72]. Naturally, mono-and polycrystalline PTs are treated separately in these cited papers.…”

Section: Wwwzamm-journalorgmentioning

confidence: 99%

“…as applied in [48]. In this article a simple habit plane-based multi-variant model has been proposed as extension of the earlier work [72], and the macroscopic Lagrangian transformation strains were computed as in monocrystal.…”

Section: Modeling Of Polycrystalsmentioning

confidence: 99%

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Contributions on the theory and computation of mono‐ and poly‐crystalline cyclic martensitic phase transformations

Sagar

Stein

2010

Z Angew Math Mech

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In this article new contributions to the theory and computation of cyclic martensitic phase transformations (PT) in monoand poly-crystalline metallic shape memory alloys are presented. The PT models of the non-convex variational problem are based on the Cauchy-Born hypothesis and Bain's principle. A quasi-convexified C 1 -continuous thermo-mechanical micromacro constitutive model for metallic monocrystals is developed which is represented together with the phase transformation constraints by a unified Lagrangian variational functional including phase evolution equations with mass conservation. The unified setting presented here includes poly-crystalline shape memory alloys whose microstructure is modeled using lattice variants. A pre-averaging scheme for randomly distributed poly-crystalline variants of transformation strains is used to transform them into those of a fictitious monocrystal. Thus, the incremental integration in process time and the spatial integration algorithms of the discrete variational problems for both mono-and poly-crystalline phase transformations can be implemented into a unified algorithm with branching for mono-and poly-crystalline phase transformations. Furthermore, an error-controlled adaptive 3D finite element method in space is presented for phase transformation problems using explicit error indicator with gradient smoothing and mesh refinements via new mesh generation in each adaptive step. Computations of informative examples with convergence studies, and comparisons with published experimental results are presented using 3D finite elements. Shape memory alloys: phenomenology, physical effects, and applicationsShape memory alloys (SMAs) have immense technological potential because of various aspects of their special thermomechanical behavior, such as shape memory effect (SME) in form of reversible quasiplastic (QP) deformation, superelasticity (SE), and bio-compatibility. Nowadays, it is widely used for biomedical systems e.g. endovascular stents, orthodontic arc wires; for controlling and activating mechanical systems such as actuators and connectors and also for structural systems e.g. vibration control devices.SMAs exhibit a strong nonlinear thermomechanical behavior associated with abrupt changes in their lattice structure called martensitic phase transformation (PT). They have intrinsic ability to transform between austenite (parent phase) and a number of symmetry-related martensitic variants (product phases). Those SMAs considered here are copper based alloy CuAlNi and nickel based alloy NiTi, which both can behave as QP and SE depending on the operating temperature.Martensitic PT is considered as a diffusionless first-order transformation between 'high' temperature, θ > A s , austenite and 'low' temperature martensitic phases, θ < M s , Fig. 1. A s and M s are the so-called austenite and martensite start temperatures. Other critical temperatures are austenite and martensite finish temperatures which are denoted by A f and M f , respectively. SMAs exhibit a specific feature...

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