geometry Geometry (; ) is, with arithmetic, one of the oldest branches of mathematics. It is concerned with properties of space such as the distance, shape, size, and relative position of figures. A mathematician who works in the field of geometry is ...

, Hermann–Mauguin notation is used to represent the symmetry elements in point groups, plane groups and

space group In mathematics, physics and chemistry, a space group is the symmetry group of an object in space, usually in three dimensions. The elements of a space group (its symmetry operations) are the rigid transformations of an object that leave it uncha ...

s. It is named after the German crystallographer

Carl Hermann Carl Heinrich Hermann (17 June 1898 – 12 September 1961), or Carl Hermann , was a German physicist and crystallographer known for his research in crystallographic symmetry, nomenclature, and mathematical crystallography in N-dimensional spa ...

(who introduced it in 1928) and the French mineralogist

Charles-Victor Mauguin Charles-Victor Mauguin (; 19 September 1878 – 25 April 1958), more often Charles Mauguin, was a French mineralogist and crystallographer. He and Carl Hermann invented an international standard notation for crystallographic groups called H ...

(who modified it in 1931). This notation is sometimes called international notation, because it was adopted as standard by the ''International Tables For Crystallography'' since their first edition in 1935. The Hermann–Mauguin notation, compared with the

Schoenflies notation The Schoenflies (or Schönflies) notation, named after the German mathematician Arthur Moritz Schoenflies, is a notation primarily used to specify point groups in three dimensions. Because a point group alone is completely adequate to describe the ...

, is preferred in crystallography because it can easily be used to include

translational symmetry In geometry, to translate a geometric figure is to move it from one place to another without rotating it. A translation "slides" a thing by . In physics and mathematics, continuous translational symmetry is the invariance of a system of equati ...

elements, and it specifies the directions of the symmetry axes.

Point groups

Rotation axes are denoted by a number ''n'' — 1, 2, 3, 4, 5, 6, 7, 8 ... (angle of rotation ''φ'' = ). For

improper rotation In geometry, an improper rotation,. also called rotation-reflection, rotoreflection, rotary reflection,. or rotoinversion is an isometry in Euclidean space that is a combination of a rotation about an axis and a reflection in a plane perpendicul ...

s, Hermann–Mauguin symbols show rotoinversion axes, unlike Schoenflies and

Shubnikov Shubnikov (russian: Шубников) is a Russian surname. Notable people with the surname include: * Alexei Vasilievich Shubnikov Alexei Vasilievich Shubnikov (russian: Алексей Васильевич Шубников; 29March 1887 – ...

notations, that shows rotation-reflection axes. The rotoinversion axes are represented by the corresponding number with a macron, ' — , , , , , , , , ... . is equivalent to a mirror plane and usually notated as ''m''. The direction of the mirror plane is defined as the direction of the perpendicular to it (the direction of the axis). Hermann–Mauguin symbols show non-equivalent axes and planes in a symmetrical fashion. The direction of a symmetry element corresponds to its position in the Hermann–Mauguin symbol. If a rotation axis ''n'' and a mirror plane ''m'' have the same direction (i.e. the plane is perpendicular to axis ''n''), then they are denoted as a fraction or ''n''/''m''. If two or more axes have the same direction, the axis with higher symmetry is shown. Higher symmetry means that the axis generates a pattern with more points. For example, rotation axes 3, 4, 5, 6, 7, 8 generate 3-, 4-, 5-, 6-, 7-, 8-point patterns, respectively.

Improper rotation In geometry, an improper rotation,. also called rotation-reflection, rotoreflection, rotary reflection,. or rotoinversion is an isometry in Euclidean space that is a combination of a rotation about an axis and a reflection in a plane perpendicul ...

axes , , , , , generate 6-, 4-, 10-, 6-, 14-, 8-point patterns, respectively. If a rotation and a rotoinversion axis generate the same number of points, the rotation axis should be chosen. For example, the combination is equivalent to . Since generates 6 points, and 3 generates only 3, should be written instead of (not , because already contains the mirror plane ''m''). Analogously, in the case when both 3 and axes are present, should be written. However we write , not , because both 4 and generate four points. In the case of the combination, where 2, 3, 6, , and axes are present, axes , , and 6 all generate 6-point patterns, as we can see on the figure in the right, but the latter should be used because it is a rotation axis — the symbol will be . Finally, the Hermann–Mauguin symbol depends on the type of the

group A group is a number of persons or things that are located, gathered, or classed together. Groups of people * Cultural group, a group whose members share the same cultural identity * Ethnic group, a group whose members share the same ethnic ide ...

Groups without higher-order axes (axes of order three or more)

These groups may contain only two-fold axes, mirror planes, and/or an inversion center. These are the

crystallographic point group In crystallography, a crystallographic point group is a set of symmetry operations, corresponding to one of the point groups in three dimensions, such that each operation (perhaps followed by a translation) would leave the structure of a crystal u ...

s 1 and (

triclinic crystal system 180px, Triclinic (a ≠ b ≠ c and α ≠ β ≠ γ ) In crystallography, the triclinic (or anorthic) crystal system is one of the 7 crystal systems. A crystal system is described by three basis vectors. In the triclinic system, the crystal i ...

), 2, ''m'', and (

monoclinic In crystallography, the monoclinic crystal system is one of the seven crystal systems. A crystal system is described by three vectors. In the monoclinic system, the crystal is described by vectors of unequal lengths, as in the orthorhombic s ...

), and 222, , and ''mm''2 ( orthorhombic). (The short form of is ''mmm''.) If the symbol contains three positions, then they denote symmetry elements in the ''x'', ''y'', ''z'' direction, respectively.

Groups with one higher-order axis

* First position — ''primary'' direction — ''z'' direction, assigned to the higher-order axis. * Second position — symmetrically equivalent ''secondary'' directions, which are perpendicular to the ''z''-axis. These can be 2, ''m'', or . * Third position — symmetrically equivalent ''tertiary'' directions, passing between ''secondary'' directions. These can be 2, ''m'', or . These are the crystallographic groups 3, 32, 3''m'', , and (

trigonal crystal system In crystallography, the hexagonal crystal family is one of the six crystal families, which includes two crystal systems (hexagonal and trigonal) and two lattice systems (hexagonal and rhombohedral). While commonly confused, the trigonal crystal ...

), 4, 422, 4''mm'', , 2''m'', , and (

tetragonal In crystallography, the tetragonal crystal system is one of the 7 crystal systems. Tetragonal crystal lattices result from stretching a cubic lattice along one of its lattice vectors, so that the cube becomes a rectangular prism with a square ...

), and 6, 622, 6''mm'', , ''m''2, , and (

hexagonal In geometry, a hexagon (from Greek , , meaning "six", and , , meaning "corner, angle") is a six-sided polygon. The total of the internal angles of any simple (non-self-intersecting) hexagon is 720°. Regular hexagon A '' regular hexagon'' has ...

). Analogously, symbols of non-crystallographic groups (with axes of order 5, 7, 8, 9 ...) can be constructed. These groups can be arranged in the following table Labeled Triangle Reflections

It can be noticed that in groups with odd-order axes ''n'' and ' the third position in symbol is always absent, because all ''n'' directions, perpendicular to higher-order axis, are symmetrically equivalent. For example, in the picture of a triangle all three mirror planes (''S''₀, ''S''₁, ''S''₂) are equivalent — all of them pass through one vertex and the center of the opposite side. For even-order axes ''n'' and ' there are secondary directions and tertiary directions. For example, in the picture of a regular hexagon one can distinguish two sets of mirror planes — three planes go through two opposite vertexes, and three other planes go through the centers of opposite sides. In this case any of two sets can be chosen as ''secondary'' directions, the rest set will be ''tertiary'' directions. Hence groups 2''m'', 2''m'', 2''m'', ... can be written as ''m''2, ''m''2, ''m''2, ... . For symbols of point groups this order usually doesn't matter; however, it will be important for Hermann–Mauguin symbols of corresponding space groups, where secondary directions are directions of symmetry elements along unit cell translations ''b'' and ''c'', while the tertiary directions correspond to the direction between unit cell translations ''b'' and ''c''. For example, symbols P''m''2 and P2''m'' denote two different space groups. This also applies to symbols of space groups with odd-order axes 3 and . The perpendicular symmetry elements can go along unit cell translations ''b'' and ''c'' or between them. Space groups P321 and P312 are examples of the former and the latter cases, respectively. The symbol of point group may be confusing; the corresponding Schoenflies symbol is ''D''_3''d'', which means that the group consists of 3-fold axis, three perpendicular 2-fold axes, and 3 vertical diagonal planes passing between these 2-fold axes, so it seems that the group can be denoted as 32''m'' or 3''m''2. However, one should remember that, unlike Schoenflies notation, the direction of a plane in a Hermann–Mauguin symbol is defined as the direction perpendicular to the plane, and in the ''D''_3''d'' group all mirror planes are perpendicular to 2-fold axes, so they should be written in the same position as . Second, these complexes generate an inversion center, which combining with the 3-fold rotation axis generates a rotoinversion axis. Groups with ''n'' = ∞ are called limit groups or

Curie group In geometry, a point group in three dimensions is an isometry group in three dimensions that leaves the origin fixed, or correspondingly, an isometry group of a sphere. It is a subgroup of the orthogonal group O(3), the group of all isometries th ...

Groups with several higher-order axes

These are the crystallographic groups of a

cubic crystal system In crystallography, the cubic (or isometric) crystal system is a crystal system where the Crystal_structure#Unit_cell, unit cell is in the shape of a cube. This is one of the most common and simplest shapes found in crystals and minerals. There ...

: 23, 432, , 3''m'', and . All of them contain four diagonal 3-fold axes. These axes are arranged as 3-fold axes in a cube, directed along its four space diagonals (the cube has symmetry). These symbols are constructed the following way: * First position — symmetrically equivalent directions of the coordinate axes ''x'', ''y'', and ''z''. They are equivalent due to the presence of diagonal 3-fold axes. * Second position — diagonal 3 or axes. * Third position — diagonal directions between any two of the three coordinate axes ''x'', ''y'', and ''z''. These can be 2, ''m'', or . All Hermann–Mauguin symbols presented above are called full symbols. For many groups they can be simplified by omitting ''n''-fold rotation axes in positions. This can be done if the rotation axis can be unambiguously obtained from the combination of symmetry elements presented in the symbol. For example, the short symbol for is ''mmm'', for is ''mm'', and for is ''m'm''. In groups containing one higher-order axis, this higher-order axis cannot be omitted. For example, symbols and can be simplified to 4/''mmm'' (or ''mm'') and 6/''mmm'' (or ''mm''), but not to ''mmm''; the short symbol for is ''m''. The full and short symbols for all 32 crystallographic point groups are given in

crystallographic point groups In crystallography, a crystallographic point group is a set of symmetry operations, corresponding to one of the point groups in three dimensions, such that each operation (perhaps followed by a translation) would leave the structure of a crystal u ...

page. Besides five cubic groups, there are two more non-crystallographic icosahedral groups (''I'' and ''I_h'' in

) and two limit groups (''K'' and ''K_h'' in

). The Hermann–Mauguin symbols were not designed for non-crystallographic groups, so their symbols are rather nominal and based on similarity to symbols of the crystallographic groups of a cubic crystal system.Shubnikov, A.V., Belov, N.V. & others, Colored Symmetry, Oxford: Pergamon Press. 1964, page 70. Group ''I'' can be denoted as 235, 25, 532, 53. The possible short symbols for ''I''_''h'' are ''m'', ''m'', ''m'm'', ''m''. The possible symbols for limit group ''K'' are ∞∞ or 2∞, and for ''K''_''h'' are ∞ or ''m'' or ∞∞''m''.

Plane groups

Plane groups can be depicted using the Hermann–Mauguin system. The first letter is either lowercase p or c to represent primitive or centered

unit cell In geometry, biology, mineralogy and solid state physics, a unit cell is a repeating unit formed by the vectors spanning the points of a lattice. Despite its suggestive name, the unit cell (unlike a unit vector, for example) does not necessaril ...

s. The next number is the rotational symmetry, as given above. The presence of mirror planes are denoted m, while

glide reflection In 2-dimensional geometry, a glide reflection (or transflection) is a symmetry operation that consists of a reflection over a line and then translation along that line, combined into a single operation. The intermediate step between reflection ...

s are only denoted g. Screw axes do not exist in two dimension, they required 3D space.

Space groups

The symbol of a

is defined by combining the uppercase letter describing the lattice type with symbols specifying the symmetry elements. The symmetry elements are ordered the same way as in the symbol of corresponding point group (group that is obtained if one removes all translational components from the space group). The symbols for symmetry elements are more diverse, because in addition to rotations axes and mirror planes, space group may contain more complex symmetry elements—screw axes (combination of rotation and translation) and glide planes (combination of mirror reflection and translation). As a result, many different space groups can correspond to the same point group. For example, choosing different lattice types and glide planes one can generate 28 different space groups from point group ''mmm'', e.g. ''Pmmm, Pnnn, Pccm, Pban, Cmcm, Ibam, Fmmm, Fddd.''

Lattice types

These are the

Bravais lattice In geometry and crystallography, a Bravais lattice, named after , is an infinite array of discrete points generated by a set of discrete translation operations described in three dimensional space by : \mathbf = n_1 \mathbf_1 + n_2 \mathbf_2 + n ...

types in three dimensions: *P — Primitive *I — Body centered (from the German "Innenzentriert") *F — Face centered (from the German "Flächenzentriert") *A — Base centered on A faces only *B — Base centered on B faces only *C — Base centered on C faces only *R — Rhombohedral

Screw axes

The

screw axis A screw axis (helical axis or twist axis) is a line that is simultaneously the axis of rotation and the line along which translation of a body occurs. Chasles' theorem shows that each Euclidean displacement in three-dimensional space has a scre ...

is noted by a number, ''n'', where the angle of rotation is . The degree of translation is then added as a subscript showing how far along the axis the translation is, as a portion of the parallel lattice vector. For example, 2₁ is a 180° (twofold) rotation followed by a translation of of the lattice vector. 3₁ is a 120° (threefold) rotation followed by a translation of of the lattice vector. The possible screw axes are: 2₁, 3₁, 3₂, 4₁, 4₂, 4₃, 6₁, 6₂, 6₃, 6₄, and 6₅. There are 4 enantiomorphic pairs of axes: (3₁ — 3₂), (4₁ — 4₃), (6₁ — 6₅), and (6₂ — 6₄). This enantiomorphism results in 11 pairs of enantiomorphic space groups, namely

Glide planes

Glide plane In geometry and crystallography, a glide plane (or transflection) is a symmetry operation describing how a reflection in a plane, followed by a translation parallel with that plane, may leave the crystal unchanged. Glide planes are noted by ''a'' ...

s are noted by ''a'', ''b'', or ''c'' depending on which axis the glide is along. There is also the ''n'' glide, which is a glide along the half of a diagonal of a face, and the ''d'' glide, which is along a quarter of either a face or space diagonal of the unit cell. The ''d'' glide is often called the diamond glide plane as it features in the

diamond Diamond is a Allotropes of carbon, solid form of the element carbon with its atoms arranged in a crystal structure called diamond cubic. Another solid form of carbon known as graphite is the Chemical stability, chemically stable form of car ...

structure. *''a'', ''b'', or ''c'' glide translation along half the lattice vector of this face. *''n'' glide translation along half a face diagonal. *''d'' glide planes with translation along a quarter of a face diagonal or of a space diagonal. *''e'' two glides with the same glide plane and translation along two (different) half-lattice vectors.

References

External links

Decoding the Hermann-Maguin Notation
- An introduction into the Hermann-Maguin notation for beginners. {{DEFAULTSORT:Hermann-Mauguin notation Crystallography Chemical nomenclature