Difference between revisions of "Unit cell"

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(See Also)
(Vectors)
 
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==Mathematical description==
 
==Mathematical description==
 
===Vectors===
 
===Vectors===
 +
There are many ways to define the Cartesian basis for the unit cell in [[real-space]]. A typical definition is:
 
:<math>\begin{array}{l}
 
:<math>\begin{array}{l}
 
\mathbf{a} = \begin{bmatrix}
 
\mathbf{a} = \begin{bmatrix}
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c \frac{ \cos{\alpha} - \cos{\beta}\cos{\gamma} }{\sin{\gamma}} \\
 
c \frac{ \cos{\alpha} - \cos{\beta}\cos{\gamma} }{\sin{\gamma}} \\
 
c \sqrt{  1 - \cos^2{\beta} - \left( \frac{\cos{\alpha} - \cos{\beta}\cos{\gamma}}{\sin{\gamma}} \right)^2 }
 
c \sqrt{  1 - \cos^2{\beta} - \left( \frac{\cos{\alpha} - \cos{\beta}\cos{\gamma}}{\sin{\gamma}} \right)^2 }
 +
\end{bmatrix}
 +
\end{array}
 +
</math>
 +
There are many mathematically equivalent ways to express a given definition. For instance, the vector <math>\mathbf{c}</math> can also be written as (c.f. [https://www.ocf.berkeley.edu/~rfu/notes/vect_unit_cells.pdf these notes] and [https://doi.org/10.1107/S0108767396005697 Trueblood et al. ''Acta Cryst'' '''1996''', A52, 770-781]):
 +
:<math>\begin{array}{l}
 +
\mathbf{c} = \begin{bmatrix}
 +
c \cos{\beta} \\
 +
-c \sin \beta \cos \alpha^{*} \\
 +
\frac{1}{c^{*}} \\
 +
\end{bmatrix}
 +
= \begin{bmatrix}
 +
c \cos{\beta} \\
 +
c \frac{\cos\alpha -\cos\beta \cos\gamma  }{\sin\gamma} \\
 +
\frac{c}{\sin\gamma} \sqrt{1 + 2 \cos\alpha\cos\beta\cos\gamma - \cos^2 \alpha - \cos^2\beta -\cos^2\gamma}\\
 
\end{bmatrix}
 
\end{bmatrix}
 
\end{array}
 
\end{array}

Latest revision as of 09:33, 14 November 2022

Example of the BCC unit cell.

The unit cell is the basic building block of a crystal lattice (whether an atomic crystal or a nanoscale superlattice). Crystalline materials have a periodic structure, with the unit cell being the minimal volume necessary to fully describe the repeating structure. There are a finite number of possible symmetries for the repeating unit cell.

A unit cell can be defined by three vectors that lie along the edges of the enclosing parallelepped. We denote the vectors as , , and ; alternately the unit cell can be described by the lengths of these vectors (, , ), and the angles between them:

, the angle between and
, the angle between and
, the angle between and


Mathematical description

Vectors

There are many ways to define the Cartesian basis for the unit cell in real-space. A typical definition is:

There are many mathematically equivalent ways to express a given definition. For instance, the vector can also be written as (c.f. these notes and Trueblood et al. Acta Cryst 1996, A52, 770-781):

Relations

Volume

If a, b, and c are the parallelepiped edge lengths, and α, β, and γ are the internal angles between the edges, the volume is

The volume of a unit cell with all edge-length equal to unity is:

Angles

  • is the angle between and
  • is the angle between and
  • is the angle between and
Unit cell definition using parallelepiped with lengths a, b, c and angles between the sides given by α,β,γ (from Wikipedia fractional coordinates).

Reciprocal vectors

The repeating structure of a unit cell creates peaks in reciprocal space. In particular, we observe maxima (constructive interference) when:

Where , , and are integers. We define reciprocal-space vectors:

And we can then express the momentum transfer () in terms of these reciprocal vectors:

Combining with the three Laue equations yields:

Where is a vector that defines the position of Bragg reflection for the reciprocal-lattice.

Examples

Cubic

Since , , and:

And in reciprocal-space:

So:

And:

Hexagonal

Since and , , and:

And in reciprocal-space:

So:

See Also