From coherent to incoherent mismatched interfaces: A generalized continuum formulation of surface stresses

Dingreville, Remi Philippe Michel; Hallil, A.; Berbenni, Stéphane

doi:10.1016/j.jmps.2014.08.003

Cited by 42 publications

(31 citation statements)

References 53 publications

(83 reference statements)

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“…When δ < 0.05, a coherent interface can be formed. When 0.05 <δ <0.25, there is the tendency to form semi-coherent interface, and when δ> 0.25, an incoherent interface is generally formed [11,12] . Assuming that the exposed external interface of the phase should be close-packed plane to reduce the interface energy [13] .…”

Section: As-castmentioning

confidence: 99%

The deformation behavior and microstructure evolution of duplex Mg-9Li-1Al alloy during superplasticity tensile testing

Liu

Zheng

Zhang

et al. 2017

IOP Conf. Ser.: Mater. Sci. Eng.

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Section: As-castmentioning

confidence: 99%

The deformation behavior and microstructure evolution of duplex Mg-9Li-1Al alloy during superplasticity tensile testing

Liu

Zheng

Zhang

et al. 2017

IOP Conf. Ser.: Mater. Sci. Eng.

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“…We note that care must be taken in determining the correct derivation and form of surface energy [59], and we begin with an integral formulation for the total free energy of a general incoherent interface as defined using the Gibbs dividing surface framework (c.f. [60]).…”

Section: Formal Definition Of Excess Free Energymentioning

confidence: 99%

“…We reiterate that many phenomena are consequently excluded from the above result; specifically, microscopic mechanisms for relaxation as a result of misfit (c.f. [60,69]) are not accounted for explicitly. This is in accordance with the model as one that finds the upper bound of the grain boundary energy; we expect accounting for microscopic relaxation mechanisms to reduce the energy.…”

Section: Interfacial Energymentioning

confidence: 99%

An analytical model of interfacial energy based on a lattice-matching interatomic energy

Runnels

Beyerlein

Conti

et al. 2016

Journal of the Mechanics and Physics of Solids

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We develop an explicit model for the interfacial energy in crystals which emphasizes the geometric origin of the cusps in the energy profile. We start by formulating a general class of interatomic energies that are reference-configuration-free but explicitly incorporate the lattice geometry of the ground state. In particular, away from the interface the energy is minimized by a perfect lattice. We build these attributes into the energy by locally matching, as best as possible, a perfect lattice to the atomic positions and then quantifying the local energy in terms of the inevitable remaining mismatch, hence the term lattice-matching used to describe the resulting interatomic energy. Based on this general energy, we formulate a simpler rigid-lattice model in which the atomic positions on both sides of the interface coincide with perfect, but misoriented, lattices. In addition, we restrict the lattice-matching operation to a binary choice between the perfect lattices on both sides of the interface. Finally, we prove an L 2 -bound on the interatomic energy and use that bound as a basis for comparison with experiment. We specifically consider symmetric tilt grain boundaries (STGB), symmetric twist grain boundaries (STwGB) and asymmetric twist grain boundaries (ATwGB) in face-centered cubic (FCC) and body-centered cubic (BCC) crystals. Two or more materials are considered for each choice of crystal structure and boundary class, with the choice of materials conditioned by the availability of molecular dynamics data. Despite the approximations made, we find very good overall agreement between the predicted interfacial energy structure and that predicted by molecular dynamics. In particular, the positions of the cusps are predicted correctly, and therefore, although surface reconstruction and faceting are not included in the model, the dominant orientations of the facets are correctly predicted by our geometrical model.

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“…The eigenstrain field ε * is also called "stress-free strain" in the sense of Eshelby (1957). It can represent thermal strains (Vinogradov and Milton, 2008;Anglin et al, 2014;Donegan and Rollett, 2015) or misfit strains (Dingreville et al, 2014;Jacques, 2016). The combination of Eq.…”

Section: Introductionmentioning

confidence: 99%

Development of a new consistent discrete green operator for FFT-based methods to solve heterogeneous problems with eigenstrains

Eloh

Jacques

Berbenni

2019

International Journal of Plasticity

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Development of a new consistent discreteGreen operator for FFT-based methods to solve heterogeneous problems with eigenstrains. International Journal of Plasticity, Elsevier, In press, Abstract In this paper, a new expression of the periodized discrete Green operator using the Discrete Fourier Transform method and consistent with the Fourier grid is derived from the classic "Continuous Green Operator" (CGO) in order to take explicitly into account the discreteness of the Discrete Fourier Transform methods. It is shown that the easy use of the conventional continuous Fourier transform of the modified Green operator (CGO approximation) for heterogeneous materials with eigenstrains leads to spurious oscillations when computing the local responses of composite materials close to materials discontinuities like interfaces, dislocations. In this paper, we also focus on the calculation of the displacement field and its associated discrete Green operator which may be useful for materials characterization methods like diffraction techniques. We show that the development of these new consistent discrete Green operators in the Fourier space named "Discrete Green Operators" (DGO) allows to eliminate oscillations while retaining similar convergence capability. For illustration, a DGO for strain-based modified Green tensor is implemented in an iterative algorithm for heterogeneous periodic composites with eigenstrain fields. Numerical examples are reported, such as the computation of the local stresses and displacements of composite materials with homogeneous or heterogeneous elasticity combined with dilatational eigenstrain or eigenstrain representing prismatic dislocation loops. The numerical stress and displacement solutions obtained with the DGO are calculated for cubic-shaped inclusions, spherical Eshelby and inhomogeneity problems. The results are discussed and compared with analytical solutions and the classic discretization method using the CGO.

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From coherent to incoherent mismatched interfaces: A generalized continuum formulation of surface stresses

Cited by 42 publications

References 53 publications

The deformation behavior and microstructure evolution of duplex Mg-9Li-1Al alloy during superplasticity tensile testing

The deformation behavior and microstructure evolution of duplex Mg-9Li-1Al alloy during superplasticity tensile testing

An analytical model of interfacial energy based on a lattice-matching interatomic energy

Development of a new consistent discrete green operator for FFT-based methods to solve heterogeneous problems with eigenstrains

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