Miller Index - Integer Vs. Irrational Miller Indices: Lattice Planes and Quasicrystals

Integer Vs. Irrational Miller Indices: Lattice Planes and Quasicrystals

Ordinarily, Miller indices are always integers by definition, and this constraint is physically significant. To understand this, suppose that we allow a plane (abc) where the Miller "indices" a, b and c (defined as above) are not necessarily integers.

If a, b and c have rational ratios, then the same family of planes can be written in terms of integer indices (hkℓ) by scaling a, b and c appropriately: divide by the largest of the three numbers, and then multiply by the least common denominator. Thus, integer Miller indices implicitly include indices with all rational ratios. The reason why planes where the components (in the reciprocal-lattice basis) have rational ratios are of special interest is that these are the lattice planes: they are the only planes whose intersections with the crystal are 2d-periodic.

For a plane (abc) where a, b and c have irrational ratios, on the other hand, the intersection of the plane with the crystal is not periodic. It forms an aperiodic pattern known as a quasicrystal. This construction corresponds precisely to the standard "cut-and-project" method of defining a quasicrystal, using a plane with irrational-ratio Miller indices. (Although many quasicrystals, such as the Penrose tiling, are formed by "cuts" of periodic lattices in more than three dimensions, involving the intersection of more than one such hyperplane.)

Read more about this topic:  Miller Index

Famous quotes containing the words irrational, miller and/or planes:

    It is not to be forgotten that what we call rational grounds for our beliefs are often extremely irrational attempts to justify our instincts.
    Thomas Henry Huxley (1825–95)

    Errors of taste are very often the outward sign of a deep fault of sensibility.
    —Jonathan Miller (b. 1936)

    After the planes unloaded, we fell down
    Buried together, unmarried men and women;
    Robert Lowell (1917–1977)