Difference between revisions of "Miller indices"
From Online Dictionary of Crystallography
AndreAuthier (talk | contribs) |
AndreAuthier (talk | contribs) |
||
| Line 5: | Line 5: | ||
=== Direct space === | === Direct space === | ||
| − | Planes of a given family of lattice planes with Miller indices | + | Planes of a given family of lattice planes with Miller indices ''h'', ''k'', ''l'' make intercepts ''OP = C a/h'', ''OQ = C b/k'', and ''OR = C c/l'' with the unit-cell axes '''OA''' = '''a''', '''OB''' = '''b''', and '''OC''' = '''c''' (see Figure 1), where ''h'', ''k'', ''l'' are prime integers and ''C'' is a constant integer; the planes of the family are denoted (''hkl''). This property results from the [[law of rational indices]]. The variation of the orientation of the planes with the ratios of the Miller indices is illustrated in the attached [[Miller_Examples| examples]]. The equation of the planes of the family is: |
<center> | <center> | ||
| Line 13: | Line 13: | ||
=== Reciprocal space === | === Reciprocal space === | ||
| − | The [[reciprocal lattice]] vector associated to the family of lattice planes is '''OH''' = ''h'' '''a*''' + ''k'' '''b*''' + ''l'' '''c*''', where '''a*''', '''b*''', '''c*''' are the reciprocal lattice basis vectors. '''OH''' is perpendicular to the family of lattice planes and ''OH'' = '' | + | The [[reciprocal lattice]] vector associated to the family of lattice planes is '''OH''' = ''h'' '''a*''' + ''k'' '''b*''' + ''l'' '''c*''', where '''a*''', '''b*''', '''c*''' are the reciprocal lattice basis vectors. '''OH''' is perpendicular to the family of lattice planes and ''OH'' = ''1''/''d'' where ''d'' is the lattice spacing of the family. |
| + | |||
| + | === Bravais-Miller indices (hexagonal axes) === | ||
| + | |||
| + | In the case of hexagonal crystals, one uses four axes, '''a<sub>1</sub>''', '''a<sub>2</sub>''', '''a<sub>3</sub>''', '''c''' and four indices, (''hkil''), where ''h'', ''k'', ''i'', ''l'' are again inversely proportional to intercepts of a plane of the family with the four axes. The indices ''h'', ''k'', ''i'' are cyclically permutable and are related by | ||
| + | |||
| + | <center> | ||
| + | ''h'' + ''k'' + ''i'' = 0 | ||
| + | </center> | ||
| + | |||
| + | === Behaviour in a change of basis === | ||
| + | |||
| + | In a change of basis the Miller indices ''h'', ''k'', ''l'' transform like the basis vectors '''a''', '''b''', '''c''' and are for that reason ''covariant'' quantities. | ||
| + | |||
| + | === Rhombohedral crystals === | ||
| + | |||
| + | The Miller indices ''h<sub>R</sub>'', ''k<sub>R</sub>'', ''l<sub>R</sub>'' with respect to rhombohedral axes are related to the corresponding indices, ''h<sub>H</sub>'', ''k<sub>H</sub>'', ''i<sub>H</sub>'',''l<sub>H</sub>'' with respect to hexagonal axes by: | ||
| + | |||
| + | |||
== History == | == History == | ||
Revision as of 07:42, 3 February 2006
(French: Indices de Miller). Spanish: Indices de Miller.)
Contents
Definition
Direct space
Planes of a given family of lattice planes with Miller indices h, k, l make intercepts OP = C a/h, OQ = C b/k, and OR = C c/l with the unit-cell axes OA = a, OB = b, and OC = c (see Figure 1), where h, k, l are prime integers and C is a constant integer; the planes of the family are denoted (hkl). This property results from the law of rational indices. The variation of the orientation of the planes with the ratios of the Miller indices is illustrated in the attached examples. The equation of the planes of the family is:
hx + ky + lz = C
Reciprocal space
The reciprocal lattice vector associated to the family of lattice planes is OH = h a* + k b* + l c*, where a*, b*, c* are the reciprocal lattice basis vectors. OH is perpendicular to the family of lattice planes and OH = 1/d where d is the lattice spacing of the family.
Bravais-Miller indices (hexagonal axes)
In the case of hexagonal crystals, one uses four axes, a1, a2, a3, c and four indices, (hkil), where h, k, i, l are again inversely proportional to intercepts of a plane of the family with the four axes. The indices h, k, i are cyclically permutable and are related by
h + k + i = 0
Behaviour in a change of basis
In a change of basis the Miller indices h, k, l transform like the basis vectors a, b, c and are for that reason covariant quantities.
Rhombohedral crystals
The Miller indices hR, kR, lR with respect to rhombohedral axes are related to the corresponding indices, hH, kH, iH,lH with respect to hexagonal axes by:
History
The Miller indices were first introduced, among others, by W. Whevell in 1829 and developed by W.H. Miller, his successor at the Chair of Mineralogy at Cambridge University, in his book A treatise on Crystallogtaphy (1839).
See also
law of rational indices
reciprocal lattice