In materials science, misorientation is the difference in crystallographic orientation between two crystallites in a polycrystalline material.
In crystalline materials, the orientation of a crystallite is defined by a transformation from a sample reference frame (i.e. defined by the direction of a rolling or extrusion process and two orthogonal directions) to the local reference frame of the crystalline lattice, as defined by the basis of the unit cell. In the same way, misorientation is the transformation necessary to move from one local crystal frame to some other crystal frame. That is, it is the distance in orientation space between two distinct orientations. If the orientations are specified in terms of matrices of direction cosines and, then the misorientation operator going from to can be defined as follows:
\begin{align} &gB=\DeltagABgA\\ &\DeltagAB=gB
| -1 | |
| g | |
| A |
\end{align}
where the term is the reverse operation of, that is, transformation from crystal frame back to the sample frame. This provides an alternate description of misorientation as the successive operation of transforming from the first crystal frame back to the sample frame and subsequently to the new crystal frame .
Various methods can be used to represent this transformation operation, such as: Euler angles, Rodrigues vectors, axis/angle (where the axis is specified as a crystallographic direction), or unit quaternions.
The effect of crystal symmetry on misorientations is to reduce the fraction of the full orientation space necessary to uniquely represent all possible misorientation relationships. For example, cubic crystals (i.e. FCC) have 24 symmetrically related orientations. Each of these orientations is physically indistinguishable, though mathematically distinct. Therefore, the size of orientation space is reduced by a factor of 24. This defines the fundamental zone (FZ) for cubic symmetries. For the misorientation between two cubic crystallites, each possesses its 24 inherent symmetries. In addition, there exists a switching symmetry, defined by:
\DeltagAB=\DeltagBA
| 1 | = | |
| 24 ⋅ 24 ⋅ 2 |
| 1 | |
| 1152 |
\DeltagAB
| crys | |
| =O | |
| B |
gB
| crys | |
| (O | |
| A |
gA)-1
The misorientation distribution (MD) is analogous to the ODF used in characterizing texture. The MD describes the probability of the misorientation between any two grains falling into a range
d\Deltag
\Deltag
Discrete misorientations or the misorientation distribution can be fully described as plots in the Euler angle, axis/angle, or Rodrigues vector space. Unit quaternions, while computationally convenient, do not lend themselves to graphical representation because of their four-dimensional nature. For any of the representations, plots are usually constructed as sections through the fundamental zone; along φ2 in Euler angles, at increments of rotation angle for axis/angle, and at constant ρ3 (parallel to <001>) for Rodrigues. Due to the irregular shape of the cubic-cubic FZ, the plots are typically given as sections through the cubic FZ with the more restrictive boundaries overlaid.
Mackenzie plots are a one-dimensional representation of the MD plotting the relative frequency of the misorientation angle, irrespective of the axis. Mackenzie determined the misorientation distribution for a cubic sample with a random texture.
The following is an example of the algorithm for determining the axis/angle representation of misorientation between two texture components given as Euler angles:
Copper [90,35,45]
S3 [59,37,63]The first step is converting the Euler angle representation, to an orientation matrix by:
| \begin{bmatrix} c | |
| \phi1 |
| c | |
| \phi2 |
| -s | |
| \phi1 |
| s | |
| \phi2 |
c\Phi&
| s | |
| \phi1 |
| c | |
| \phi2 |
| +c | |
| \phi1 |
| s | |
| \phi2 |
c\Phi&
| s | |
| \phi2 |
s\Phi
| \ -c | |
| \phi1 |
| s | |
| \phi2 |
| -s | |
| \phi1 |
| c | |
| \phi2 |
c\Phi&
| -s | |
| \phi1 |
| s | |
| \phi2 |
| +c | |
| \phi1 |
| c | |
| \phi2 |
c\Phi&
| c | |
| \phi2 |
s\Phi
| \ s | |
| \phi1 |
s\Phi&
| -c | |
| \phi1 |
s\Phi&c\Phi\end{bmatrix}
where and represent and of the respective Euler component. This yields the following orientation matrices:
gcopper=\begin{bmatrix} -0.579&0.707&0.406\\ -0.579&-0.707&0.406\\ 0.574&0&0.819\\ \end{bmatrix}
gS3=\begin{bmatrix} -0.376&0.756&0.536\\ -0.770&-0.577&0.273\\ 0.516&-0.310&0.799\\ \end{bmatrix}
The misorientation is then:
\DeltagAB=gcopper
| -1 | |
| g | |
| S3 |
=\begin{bmatrix} 0.970&0.149&-0.194\\ -0.099&0.965&0.244\\ 0.224&-0.218&0.950\\ \end{bmatrix}
The axis/angle description (with the axis as a unit vector) is related to the misorientation matrix by:
\begin{align} &\cos\Theta=
| g11+g22+g33-1 | |
| 2 |
\\ &r1=
| g23-g32 | |
| 2\sin\Theta |
\\ &r2=
| g31-g13 | |
| 2\sin\Theta |
\\ &r3=
| g12-g21 | |
| 2\sin\Theta |
\end{align}
For the copper—S3 misorientation given by, the axis/angle description is 19.5° about [0.689,0.623,0.369], which is only 2.3° from <221>. This result is only one of the 1152 symmetrically related possibilities but does specify the misorientation. This can be verified by considering all possible combinations of orientation symmetry (including switching symmetry).