In continuum mechanics an eigenstrain is any mechanical deformation in a material that is not caused by an external mechanical stress, with thermal expansion often given as a familiar example. The term was coined in the 1970s by Toshio Mura, who worked extensively on generalizing their mathematical treatment.[1] A non-uniform distribution of eigenstrains in a material (e.g., in a composite material) leads to corresponding eigenstresses, which affect the mechanical properties of the material.[2]

Overview

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Many distinct physical causes for eigenstrains exist, such as crystallographic defects, thermal expansion, the inclusion of additional phases in a material, and previous plastic strains.[3] All of these result from internal material characteristics, not from the application of an external mechanical load. As such, eigenstrains have also been referred to as “stress-free strains”[4] and “inherent strains”.[5] When one region of material experiences a different eigenstrain than its surroundings, the restraining effect of the surroundings leads to a stress state on both regions.[6] Analyzing the distribution of this residual stress for a known eigenstrain distribution or inferring the total eigenstrain distribution from a partial data set are both two broad goals of eigenstrain theory.

Analysis of eigenstrains and eigenstresses

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Eigenstrain analysis usually relies on the assumption of linear elasticity, such that different contributions to the total strain   are additive. In this case, the total strain of a material is divided into the elastic strain e and the inelastic eigenstrain  :

 

where   and   indicate the directional components in 3 dimensions in Einstein notation.

Another assumption of linear elasticity is that the stress   can be linearly related to the elastic strain   and the stiffness   by Hooke’s Law:[3]

 

In this form, the eigenstrain is not in the equation for stress, hence the term "stress-free strain". However, a non-uniform distribution of eigenstrain alone will cause elastic strains to form in response, and therefore a corresponding elastic stress. When performing these calculations, closed-form expressions for   (and thus, the total stress and strain fields) can only be found for specific geometries of the distribution of  .[5]

Ellipsoidal inclusion in an infinite medium

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Ellipsoidal eigenstrain inclusion

One of the earliest examples providing such a closed-form solution analyzed a ellipsoidal inclusion of material   with a uniform eigenstrain, constrained by an infinite medium   with the same elastic properties.[6] This can be imagined with the figure on the right. The inner ellipse represents the region  . The outer region represents the extent of   if it fully expanded to the eigenstrain without being constrained by the surrounding  . Because the total strain, shown by the solid outlined ellipse, is the sum of the elastic and eigenstrains, it follows that in this example the elastic strain in the region   is negative, corresponding to a compression by   on the region  .

The solutions for the total stress and strain within   are given by:

 
 

Where   is the Eshelby Tensor, whose value for each component is determined only by the geometry of the ellipsoid. The solution demonstrates that the total strain and stress state within the inclusion   are uniform. Outside of  , the stress decays towards zero with increasing distance away from the inclusion. In the general case, the resulting stresses and strains may be asymmetric, and due to the asymmetry of  , the eigenstrain may not be coaxial with the total strain.

Inverse problem

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Eigenstrains and the residual stresses that accompany them are difficult to measure (see:Residual stress). Engineers can usually only acquire partial information about the eigenstrain distribution in a material. Methods to fully map out the eigenstrain, called the inverse problem of eigenstrain, are an active area of research.[5] Understanding the total residual stress state, based on knowledge of the eigenstrains, informs the design process in many fields.

Applications

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Structural engineering

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Residual stresses, e.g. introduced by manufacturing processes or by welding of structural members, reflect the eigenstrain state of the material.[5] This can be unintentional or by design, e.g. shot peening. In either case, the final stress state can affect the fatigue, wear, and corrosion behavior of structural components.[7] Eigenstrain analysis is one way to model these residual stresses.

Composite materials

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Since composite materials have large variations in the thermal and mechanical properties of their components, eigenstrains are particularly relevant to their study. Local stresses and strains can cause decohesion between composite phases or cracking in the matrix. These may be driven by changes in temperature, moisture content, piezoelectric effects, or phase transformations. Particular solutions and approximations to the stress fields taking into account the periodic or statistical character of the composite material's eigenstrain have been developed.[2]

Strain engineering

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Lattice misfit strains are also a class of eigenstrains, caused by growing a crystal of one lattice parameter on top of a crystal with a different lattice parameter.[8] Controlling these strains can improve the electronic properties of an epitaxially grown semiconductor.[9] See: strain engineering.

See also

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References

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  1. ^ Kinoshita, N.; Mura, T. (1971). "Elastic fields of inclusions in anisotropic media". Physica Status Solidi A. 5 (3): 759–768. doi:10.1002/pssa.2210050332.
  2. ^ a b Dvorak, George J. (2013). Micromechanics of Composite Materials. Springer Science. ISBN 978-94-007-4100-3.
  3. ^ a b Mura, Toshio (1987). Micromechanics of Defects in Solids (Second, Revised ed.). Kluwer Academic Publishers. ISBN 978-90-247-3256-2.
  4. ^ Robinson, Kenneth (1951). "Elastic Energy of an Ellipsoidal Inclusion in an Infinite Solid". Journal of Applied Physics. 22 (8): 1045. doi:10.1063/1.1700099.
  5. ^ a b c d Jun, Tea-Sung; Korsunsky, Alexander M. (2010). "Evaluation of residual stresses and strains using the Eigenstrain Reconstruction Method". International Journal of Solids and Structures. 47 (13): 1678–1686. doi:10.1016/j.ijsolstr.2010.03.002.
  6. ^ a b Eshelby, John Douglas (1957). "The determination of the elastic field of an ellipsoidal inclusion, and related problems" (PDF). Proceedings of the Royal Society A. 241 (1226): 376–396. doi:10.1098/rspa.1957.0133. S2CID 122550488.
  7. ^ Faghidian, S Ali (2014). "Contents Full Article Content List Abstract IntroductionDetermination of the residual fieldsMathematical theory of reconstructionResults and discussionConclusion References Figures & Tables Article Metrics Related Articles Cite Share Request Permissions Explore More Download PDF Inverse determination of the regularized residual stress and eigenstrain fields due to surface peening". The Journal of Strain Analysis for Engineering Design. 50 (2): 84–91. doi:10.1177/0309324714558326. S2CID 138848957.
  8. ^ Tirry, Wim; Schryvers, Dominique (2009). "Linking a completely three-dimensional nanostrain to a structural transformation eigenstrain". Nature Materials. 8 (9): 752–7. doi:10.1038/nmat2488. PMID 19543276.
  9. ^ Hue, Florian; Hytch, Martin; Bender, Hugo; Houdellier, Florent; Claverie, Alain (2008). "Direct Mapping of Strain in a Strained Silicon Transistor by High-Resolution Electron Microscopy" (PDF). Physical Review Letters. 100 (15): 156602. doi:10.1103/PhysRevLett.100.156602. PMID 18518137. S2CID 42476637.