Microstructure*Proper-es.pajarito.materials.cmu.edu/rollett/27301/L10... · 2 Objective+ • The’objecDve’of’this’lecture’is’to’provide’a...
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27-‐301 Microstructure-‐Proper-es
Tensors and Anisotropy, Part 3 Profs. A. D. Rolle<, M. De Graef
Microstructure Properties
Processing Performance
Last modi.ied: 18th Oct. ‘15
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Objective • The objecDve of this lecture is to provide a mathemaDcal framework for the descripDon of properDes, especially when they vary with direcDon.
• A basic property that occurs in almost applicaDons is elas%city. Although elasDc response is linear for all pracDcal purposes, it is oKen anisotropic (composites, textured polycrystals etc.).
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Why does it matter? • Even an apparently simple device such as quartz oscillator is made from a
single crystal (of quartz) whose elasDc properDes are crucial to the device performance.
• The microstructure of wood consists of bundles of elongated cells at the 1-‐100 µm scale. The cell walls themselves have a strongly aligned microstructure. This means that wood is inevitably a strongly anisotropic material. Engineering with such a material requires quanDtaDve descripDons of its anisotropy.
• Any fiber reinforced composite is anisotropic because the fibers generally have higher modulus than their matrix. The symmetry that applies depends on the way in which the fibers are laid up, e.g. unidirecDonal versus random in-‐plane versus woven.
• The bo<om line is that many engineering materials at all different length scales are anisotropic (and not just elasDcally), so the analysis that we do here is needed for quanDtaDve descripDons.
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Q&A 1. How do we write the relaDonship between (tensor) stress and (tensor) strain? σ=C:ε. How about the other way around? ε=S:σ. What are “sDffness” and “compliance” in this context? The sDffness tensor is the collecDon of coefficients that connect all the different stress coefficients/components to all the different strain coefficients/components. How do we express this in Voigt or vector-‐matrix notaDon? The only difference is that the stress and strain are vectors and the sDffness and compliance are matrices. If indices are used then stress and strain each have two indices and the sDffness and compliance each have four.
2. What are the relaDonships between the coefficients of the (4th rank) sDffness tensor and the sDffness matrix (6x6)? See the notes for details but, e.g., {11,22,33}tensor correspond to {1,2,3}matrix. E.g. C12(matrix)=C1122(tensor). What about the compliance tensor and matrix? Here, more care is required because certain coefficients have factors of 2 or 4.
3. What does work conjugacy mean? The energy stored in a body when elasDc strains and stresses are present is calculated as the product of the stress and strain, which means that the work done makes the strain and stress conjugate (joined) variables. What does this mean for the relaDonships between (2nd rank) tensor stress and its vector form? What about strain? Answering these two together, we note that work conjugacy means that whatever notaDon is used to express stress and strain, the product of the two must be the same because of conservaDon of energy. This then explains why factors of two are used in the conversion to/from matrix to tensor representaDons of the shear components of strain (but not the normal strain components). These factors of two could have been applied to stress, but by convenDon we do this for strain.
4. How do we write the tensor transformaDon rule in vector-‐matrix notaDon? See the notes for details but the basic idea is that a 6x6 matrix (that can be applied to a sDffness or compliance tensor) is formed from the coefficients of the transformaDon matrix.
5. How do we apply crystal symmetry to elasDc moduli (e.g. the sDffness tensor)? We apply a symmetry operator to the (sDffness) tensor and set the new and old versions of the tensor equal to each other, coefficient by coefficient. What net effect does it have on the sDffness matrix for cubic materials? Applying the cubic crystal symmetry to the sDffness tensor reduces most of the coefficients to zero and there are only 3 independent coefficients that remain.
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Q&A, part 2 6. How do we convert from sDffness to compliance (and vice versa)? The detailed mathemaDcs is out of
scope for this course. It is sufficient to know that the two tensors combine to form a 4th rank idenDty tensor, from which one can obtain algebraic relaDonships as given in the notes. Be aware that these formulae depend on the crystal symmetry (as do the compliance & sDffness tensors themselves).
7. How do we apply symmetry (and transformaDons of axes in general) to the property of anisotropic elasDcity? There are two answers. The first answer is that one can apply the tensor transformaDon rule, just as explained in previous lectures. Generate the transformaDon matrix with any the methods described (i.e. dot products between old and new axes, or using the combinaDon of axis and angle). Then write out the transformaDon with 4 copies of the matrix taking care to specify the indices correctly. The alternaDve answer is to generate a 6x6 transformaDon matrix that can be used with vector-‐matrix (Voigt) notaDon for either the stress, strain (6x1) vectors or the modulus (6x6) matrix.
8. How do we show that symmetry reduces the number of independent coefficients in an anisotropic elasDcity modulus tensor? Given a symmetry matrix, one proceeds just as in the previous examples i.e. apply symmetry and then equate individual coefficients to find the cases of either zero or equality(between different coefficients).
9. How do we calculate the (anisotropic) elasDc (Young’s) modulus in an arbitrary direcDon? This looks ahead to the next lecture. The idea is to realize that a tensile test is such that there is only one non-‐zero coefficient in the stress tensor (or vector); the strain tensor, however, has to have more than one non-‐zero coefficient (because of the Poisson effect). Therefore one uses the relaDonship that strain = compliance x stress. By rotaDng the compliance tensor such that one axis (usually x) is parallel to the desired direcDon, one obtains the Young’s modulus in that direcDon as 1/S11.
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Notation F SDmulus (field) R Response P Property j electric current E electric field D electric polarizaDon ε Strain σ Stress (or conducDvity) ρ ResisDvity d piezoelectric tensor
C elasDc sDffness (also k) S elasDc compliance a rotaDon matrix W work done (energy) I idenDty matrix O symmetry operator (matrix)
Y Young’s modulus δ Kronecker delta e axis (unit) vector T tensor α direcDon cosine
If the stress or strain symbol is written with one index then vector-‐matrix notation is being used; two indices indicate tensor notation. Similarly 2 indices on S or C denote vector-‐matrix and 4 denote tensor notation.
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Linear properties • Certain properDes, such as elasDcity in most cases, are linear which means that we can simplify even further to obtain
R = R0 + PF or if R0 = 0,
R = PF. e.g. elasDcity: σ = C ε In tension, C ≡ Young’s modulus, Y or E.
stiffness
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Elasticity • Elas%city: example of a property that requires 4th rank tensors to describe it fully.
• Even in cubic metals, a crystal can be quite anisotropic. The [111] in many cubic metals is sDffer than the [100] direcDon, although there some where the opposite is true.
• Even in cubic materials, 3 different numbers/coefficients/moduli are required to describe elasDc properDes; isotropic materials only require 2.
• Familiarity with Miller indices is assumed.
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Stress Tensor Illustration of the action of each stress component on each face of an inQinitesimal cubical volume element.
Note how the diagonal components act normal to each face, whereas the shear components exert transverse tractions.
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Elastic Anisotropy: 1 • First we restate the linear elasDc relaDons for the
properDes Compliance, wri<en S, and S%ffness, wri<en C (!), which connect stress, σ, and strain, ε. We write it first in vector-‐tensor notaDon with “:” signifying inner product (i.e. add up terms that have a common suffix or index in them):
σ = C:ε ε = S:σ
• In component form (with suffixes), σij = Cijklεkl εij = Sijklσkl
• In vector-‐matrix form (with suffixes, to be explained), σi = Cijεj εi = Sijσj
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Elastic Anisotropy: 2 The definiDons of the stress and strain tensors mean that
they are both symmetric (second rank) tensors. Therefore we can see that
ε23 = S2311σ11 ε32 = S3211σ11 = ε23
which means that, S2311 = S3211
and in general, Sijkl = Sjikl
We will see later on that this reduces considerably the number of different coefficients needed.
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Stiffness in sample coords. • Consider how to express the elasDc properDes of a single
crystal in the sample coordinates. In this case we need to rotate the (4th rank) tensor from crystal coordinates to sample coordinates using the orientaDon (matrix), a (see parts 1 & 2):
cijkl' = aimajnakoalpcmnop
• Note how the transformaDon matrix appears four Dmes because we are transforming a 4th rank tensor!
• The axis transformaDon matrix, a, is also wri<en as λ in some texts.
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Young’s modulus from compliance • Young's modulus as a funcDon of direcDon can be obtained from the compliance tensor as E=1/s'1111.
• Using compliances and a stress boundary condiDon (only σ11≠0) is most straighvorward. To obtain s'1111, we simply apply the same transformaDon rule,
s'ijkl = aim ajn ako alpsmnop which, subsDtuDng “1” for i, j, k & l, becomes
s’1111 = a1m a1n a1o a1psmnop
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Voigt or “matrix” notation • It is useful to re-‐express the three quanDDes involved in a simpler format. The stress and strain tensors are vectorized, i.e. converted into a 1x6 notaDon and the elasDc tensors are reduced to 6x6 matrices. σ11 σ12 σ13σ 21 σ 22 σ 23
σ 31 σ 32 σ33
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σ1 σ 6 σ 5
σ 6 σ 2 σ 4
σ 5 σ 4 σ 3
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← → * σ1,σ 2,σ3,σ4 ,σ 5,σ 6( )Newnham, Ch. 10
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Voigt or “matrix” notation, contd. • Similarly for strain: The parDcular definiDon of shear strain used in the reduced notaDon happens to correspond to that used in mechanical engineering such that ε4 is the change in angle between direcDon 2 and direcDon 3 due to deformaDon.
ε11 ε12 ε13ε21 ε22 ε23ε31 ε32 ε33
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ε112ε6
12ε5
12ε6 ε2
12 ε4
12 ε5
12 ε4 ε3
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← → * ε1,ε2 ,ε3,ε4,ε5,ε6( )
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Work conjugacy, matrix inversion • The more important consideraDon is that the reason for
the factors of two is so that work conjugacy is maintained. Stress and strain are linked (conjugated) because it is their product that gives the energy associated with elasDc loading. dW = σ:dε = σij : dεij = σk • dεk This means that the 6x6 matrix of sDffness coefficients is symmetric, i.e. Cij = Cji. Likewise, Sij = Sji.
• Also we can combine the expressions σ = Cε and ε = Sσ to give:
σ = CSσ, which shows that: I = CS, or, C = S-‐1
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Tensor conversions: stiffness
• Lastly we need a system for converDng the tensor coefficients of sDffness and compliance (4 indices) to the matrix coefficients (2 indices). For sDffness, it is very simple because one subsDtutes values according to the following table, such that matrixC11 = tensorC1111 for example.
Tensor 11 22 33 23 32 13 31 12 21Matrix 1 2 3 4 4 5 5 6 6
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(General) Stiffness Matrix
C =
C11 C12 C13 C14 C15 C16C12 C22 C23 C24 C25 C26C13 C23 C33 C34 C35 C36C14 C24 C34 C44 C45 C46C15 C25 C35 C45 C55 C56C16 C26 C36 C46 C56 C66
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&&&&&&&&
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Vector-‐matrix notation (two indices for the moduli, one index for stress or strain)
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Tensor conversions: compliance • For compliance some factors of two are required (by work conjugacy) and so the rule becomes:
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pSijkl = Smnp =1 m AND n∈ 1,2,3[ ]p = 2 m XOR n∈ 1,2,3[ ]p = 4 m AND n∈ 4,5,6[ ]
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Axis Transformations • It is sDll possible to perform axis transformaDons, as
allowed for by the Tensor Rule. The coefficients can be combined [Newnham] together into a 6 by 6 matrix that can be used for 2nd rank tensors such as stress and strain, below.
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• Stress (in vector notaDon) transforms as: X’i = αij Xj
• Strain (in vector notaDon) transforms as: x’i = (α-1
ij)T xj where superscript “T” signifies transpose of the matrix.
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Relationships between coef.icients: C in terms of S
• Recall that we stated that the compliance and sDffness tensors are the inverse of each other, or, C = S-‐1.
• Determining the relaDonship can be done, but not required here.
• Useful relaDonships between coefficients for cubic materials are as follows. Symmetrical relaDonships exist for compliance coefficients in terms of sDffness values (next slide). C11 = (S11+S12)/{(S11-‐S12)(S11+2S12)} C12 = -‐S12/{(S11-‐S12)(S11+2S12)} C44 = 1/S44.
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S in terms of C
The relaDonships for S (compliance) in terms of C (sDffness) are symmetrical to those for sDffnesses in terms of compliances (a simple exercise in algebra!). S11 = (C11+C12)/{(C11-‐C12)(C11+2C12)} S12 = -‐C12/{(C11-‐C12)(C11+2C12)} S44 = 1/C44.
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Effect of symmetry on stiffness matrix • Why do we need to look at the effect of symmetry? For a
cubic material, only 3 independent coefficients are needed as opposed to the 81 coefficients in a 4th rank tensor. The reason for this is the symmetry of the material.
• What does symmetry mean? Fundamentally, if you pick up a crystal, rotate [mirror] it and put it back down, then a symmetry operaDon [rotaDon, mirror] is such that you cannot tell that anything happened.
• From a mathemaDcal point of view, this means that the property (its coefficients) does not change. For example, if the symmetry operator changes the sign of a coefficient, then it must be equal to zero.
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Effect of symmetry on stiffness matrix • Following Reid, p.66 et seq.: Apply a -‐90° rotaDon about the crystal-‐z axis (axis 3)*, C’ijkl = OimOjnOkoOlpCmnop: C’ = C!
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O4z =
0 1 0−1 0 00 0 1
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*Reid describes this as +90°, but -‐90° reproduces his result (because he apparently considers posiDve to be clockwise).
!C =
C22 C21 C23 C25 −C24 −C26C21 C11 C13 C15 −C14 −C16C23 C13 C33 C35 −C34 −C36C25 C15 C35 C55 −C54 −C56−C24 −C14 −C34 −C54 C44 C46−C26 −C16 −C36 −C56 C46 C66
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Effect of symmetry, 2 • Using P’ = P, we can equate all the coefficients in the 6x6 matrix and find that: C11=C22, C13=C23, C44=C35, C16=-‐C26, C14=C15 = C24 = C25 = C34 = C35 = C36 = C45 = C46 = C56 = 0.
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" C =
C11 C12 C13 0 0 C16
C12 C11 C13 0 0 −C16
C13 C13 C33 0 0 00 0 0 C44 0 00 0 0 0 C44 C46
C16 −C16 0 0 C46 C66
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Stiffness matrix, cubic symmetry • Thus by repeated applicaDons of the symmetry operators, one can
demonstrate (for cubic crystal symmetry) that one can reduce the 81 coefficients down to only 3 independent quanDDes. In fact, one need only apply two successive 90° rotaDons about two orthogonal axes (e.g., 100 and 010) to demonstrate this result. The number of coefficients decreases to two in the case of isotropic elasDcity.
C11 C12 C12 0 0 0C12 C11 C12 0 0 0C12 C12 C11 0 0 00 0 0 C44 0 00 0 0 0 C44 00 0 0 0 0 C44
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Examinable
Symmetrized 6x6 matrices for other point groups given on next slide. Please acknowledge Carnegie Mellon if you make public use of these slides
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Summary
• We have covered the following topics: – Linear elasDcity – SDffness (C) and Compliance (S) tensors – Tensor versus vector-‐matrix notaDon for stress, strain and elasDc tensors, with conversion factors.
– Effect of symmetry in stress, strain tensors. – ElasDcity, reducDon in number of independent coefficients as example as how to apply (crystal) symmetry.
– Isotropic elasDcity: moduli, Lamé constants
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Supplemental Slides • The following slides contain some useful material for those who are not familiar with all the detailed mathemaDcal methods of matrices, transformaDon of axes etc.
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Bibliography • R.E. Newnham, Proper'es of Materials: Anisotropy, Symmetry, Structure, Oxford
University Press, 2004, 620.112 N55P. • De Graef, M., lecture notes for 27-‐201. • Nye, J. F. (1957). Physical Proper%es of Crystals. Oxford, Clarendon Press. • Kocks, U. F., C. Tomé & R. Wenk, Eds. (1998). Texture and Anisotropy, Cambridge
University Press, Cambridge, UK. • T. Courtney, Mechanical Behavior of Materials, McGraw-‐Hill, 0-‐07-‐013265-‐8. • Landolt, H.H., Börnstein, R., 1992. Numerical Data and Func%onal Rela%onships in
Science and Technology, III/29/a. Second and Higher Order ElasDc Constants. Springer-‐Verlag, Berlin.
• Zener, C., 1960. Elas%city And Anelas%city Of Metals, The University of Chicago Press. • GurDn, M.E., 1972. The linear theory of elasDcity. Handbuch der Physik, Vol. VIa/2.
Springer-‐Verlag, Berlin, pp. 1–295. • HunDngton, H.B., 1958. The elasDc constants of crystals. Solid State Physics 7, 213–351. • Love, A.E.H., 1944. A Trea%se on the Mathema%cal Theory of Elas%city, 4th Ed., Dover,
New York. • Newey, C. and G. Weaver (1991). Materials Principles and Prac%ce. Oxford, England,
Bu<erworth-‐Heinemann. • Reid, C. N. (1973). Deforma%on Geometry for Materials Scien%sts. Oxford, UK,
Pergamon.
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Mathematical Descriptions
• MathemaDcal descripDons of properDes are available. • MathemaDcs, or a type of mathemaDcs provides a
quan%ta%ve framework. It is always necessary, however, to make a correspondence between mathemaDcal variables and physical quanDDes.
• In group theory one might say that there is a set of mathemaDcal operaDons & parameters, and a set of physical quanDDes and processes: if the mathemaDcs is a good descripDon, then the two sets are isomorphous.
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Non-‐Linear properties, example • Another important example of non-‐linear properDes is plasDcity, i.e.
the irreversible deformaDon of solids. • A typical descripDon of the response at plasDc yield
(what happens when you load a material to its yield stress) is elasDc-‐perfectly plasDc. In other words, the material responds elasDcally unDl the yield stress is reached, at which point the stress remains constant (strain rate unlimited).
˙ ε = σσ yield
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n• A more realisDc descripDon is a power-‐law with a large exponent, n~50. The stress is scaled by the crss, and be expressed as either shear stress-‐ shear strain rate [graph], or tensile stress-‐tensile strain [equaDon].
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Einstein Convention • The Einstein ConvenDon, or summaDon rule for suffixes looks like this:
Ai = Bij Cj Ai = ΣjBij Cj
where “i” and “j” both are integer indexes whose range is {1,2,3}. So, to find each “ith” component of A on the LHS, we sum up over the repeated index, “j”, on the RHS:
A1 = B11C1 + B12C2 + B13C3 A2 = B21C1 + B22C2 + B23C3 A3 = B31C1 + B32C2 + B33C3
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Matrix Multiplication • Take each row of the LH matrix in turn and mulDply it into each column of the RH matrix.
• In suffix notaDon, aij = bikckj
aα + bδ + cλ aβ + bε + cµ aγ + bφ + cνdα + eδ + f λ dβ + eε + fµ dγ + eφ + fνlα +mδ + nλ lβ +mε + nµ lγ +mφ + nν
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α β γ
δ ε φ
λ µ ν
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Properties of Rotation Matrix • The rotaDon matrix is an orthogonal matrix, meaning that
any row is orthogonal to any other row (the dot products are zero). In physical terms, each row represents a unit vector that is the posiDon of the corresponding (new) old axis in terms of the (old) new axes.
• The determinant = +1. • The same applies to columns: in suffix notaDon -‐
aijakj = δik, ajiajk = δik
a b cd e fl m n
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ad+be+cf = 0
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-
Matrix representation of the rotation point groups
What is a group? A group is a set of objects that form a closed set: if you combine any two of them together, the result is simply a different member of that same group of objects. Rotations in a given point group form closed sets - try it for yourself!
Note: the 3rd matrix in the 1st column (x-diad) is missing a “-” on the 33 element; this is corrected in this slide. Also, in the 2nd from the bottom, last column: the 33 element should be +1, not -1. In some versions of the book, in the last matrix (bottom right corner) the 33 element is incorrectly given as -1; here the +1 is correct.
Kocks, Tomé & Wenk:��� Ch. 1 Table II
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Homogeneity • SDmuli and responses of interest are, in general, not scalar
quanDDes but tensors. Furthermore, some of the properDes of interest, such as the plasDc properDes of a material, are far from linear at the scale of a polycrystal. Nonetheless, they can be treated as linear at a suitably local scale and then an averaging technique can be used to obtain the response of the polycrystal. The local or microscopic response is generally well understood but the validity of the averaging techniques is sDll controversial in many cases. Also, we will only discuss cases where a homogeneous response can be reasonably expected.
• There are many problems in which a non-‐homogeneous response to a homogeneous sDmulus is of criDcal importance. Stress-‐corrosion cracking, for example, is an extremely non-‐linear, non-‐homogeneous response to an approximately uniform sDmulus which depends on the mechanical and electro-‐chemical properDes of the material.
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The “RVE” • In order to describe the properDes of a material, it is useful to define a representa%ve volume element (RVE) that is large enough to be staDsDcally representaDve of that region (but small enough that one can subdivide a body).
• For example, consider a polycrystal: how many grains must be included in order for the element to be representaDve of that point in the material?
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Transformations of Stress & Strain Vectors • It is useful to be able to transform the axes of
stress tensors when wri<en in vector form (equaDon on the leK). The table (right) is taken from Newnham’s book. In vector-‐matrix form, the transformaDons are:
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α41 α42 α43 α44 α45 α46
α51 α52 α53 α54 α55 α56
α61 α62 α63 α64 α65 α66
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" σ i =α ijσ j
σ i =α ij−1 " σ j
" ε i =α ij−1Tε j
εi =α ijT " ε j
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Use of MuPAD inside Matlab • Note that the 6x6 transformaDon matrix can be programmed inside Matlab just as a 3x3 can.
• In order to apply a transformaDon (e.g. a symmetry operator) to a 6x6 sDffness or compliance matrix, the formula is the same as before, i.e.: C’= O C OT
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