Hysteresis and Stick-Slip Motion of Phase Boundaries in Dynamic Models of Phase Transitions

Vainchtein, Anna; Rosakis, Phoebus

doi:10.1007/s003329900083

Cited by 32 publications

(22 citation statements)

References 34 publications

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“…As such, the system becomes more stable and hysteresis tends to vanish. 7,26 Based on the above rationale, a multiscale model is established recently, 7 where the variation of hysteresis loop area (H) with GS(l) can be approximated by a simple scaling law as…”

Section: 2mentioning

confidence: 99%

Stress hysteresis and temperature dependence of phase transition stress in nanostructured NiTi—Effects of grain size

Ahadi¹,

Sun²

2013

Appl. Phys. Lett.

213

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Section: 2mentioning

confidence: 99%

Stress hysteresis and temperature dependence of phase transition stress in nanostructured NiTi—Effects of grain size

Ahadi¹,

Sun²

2013

Appl. Phys. Lett.

213

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“…A model, sometimes also called Eriksen's bar, describes phase transitions in an elastic bar of a two-phase material. Although rather simpliÿed, this model can capture many qualitative features typical for materials that undergo phase transformations and has been used for numerical simulations in visco-elastic models in References [12,20,23]. We use the usual form of the double-well potential…”

Section: Visco-elasto-plasticmentioning

confidence: 99%

“…Mathematical problems that arise in this isothermal model has been thoroughly studied by Ball et al [14], Friesecke and McLeod [15], Pego [16], Rybka [17] and Ho mann [18], and Swart and Holmes [19], in some cases even with ÿ =0; for numerical treatment see References [12,[20][21][22][23].…”

mentioning

confidence: 99%

Visco‐elasto‐plastic model for martensitic phase transformation in shape‐memory alloys

Plecháč

Roubíček

2002

Math Methods in App Sciences

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Communicated by P. Colli SUMMARY Evolution of ÿne structure in martensite undergoing an isothermal process is modelled on a microscopic level by using a positive homogeneous dissipation potential which can re ect a speciÿc energy needed for a phase transformation between di erent variants of martensite. The model thus naturally incorporates an activation phenomenon. Existence of a weak solution is proved together with convergence of ÿnite-element approximations. Numerical experiments showing the expected rate-independent hysteresis response are also presented.

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“…The twin boundary propagates through successive nucleation, glide and annihilation of a partial dislocation. These events are the source of energy dissipation during loading [11]. As the twin boundary sweeps through the wire, the wire progressively transforms into the new 001…”

Section: Tensile Loading and Unloading Behavior Of Cu Nanowiresmentioning

confidence: 99%

Mechanism for the Pseudoelastic Behavior of FCC Shape Memory Nanowires

2008

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Pseudoelasticity and shape memory have been recently discovered in single-crystalline FCC nanowires of Cu, Ni, Au and Ag. The deformation mechanism responsible for this novel behavior is surface-stress-driven reorientations of the FCC lattice structure. A mechanismbased continuum model has been developed for the lattice reorientation process during loading through the propagation of a single twin boundary. Here, this model is extended to the nucleation, propagation and annihilation of multiple twin boundaries associated with the reverse reorientation process during unloading. The extended model captures the major characteristics of the loading and unloading behavior and highlights the dominating effect of the evolution of twin boundary structure on the pseudoelasticity.

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Hysteresis and Stick-Slip Motion of Phase Boundaries in Dynamic Models of Phase Transitions

Cited by 32 publications

References 34 publications

Stress hysteresis and temperature dependence of phase transition stress in nanostructured NiTi—Effects of grain size

Stress hysteresis and temperature dependence of phase transition stress in nanostructured NiTi—Effects of grain size

Visco‐elasto‐plastic model for martensitic phase transformation in shape‐memory alloys

Mechanism for the Pseudoelastic Behavior of FCC Shape Memory Nanowires

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