Crystallographic point group

Template:Short description In crystallography, a crystallographic point group is a three dimensional point group whose symmetry operations are compatible with a three dimensional crystallographic lattice. According to the crystallographic restriction it may only contain one-, two-, three-, four- and sixfold rotations or rotoinversions. This reduces the number of crystallographic point groups to 32 (from an infinity of general point groups). These 32 groups are one-and-the-same as the 32 types of morphological (external) crystalline symmetries derived in 1830 by Johann Friedrich Christian Hessel from a consideration of observed crystal forms. In 1867 Axel Gadolin, who was unaware of the previous work of Hessel, found the crystallographic point groups independently using stereographic projection to represent the symmetry elements of the 32 groups.^[1]Template:Rp

In the classification of crystals, to each space group is associated a crystallographic point group by "forgetting" the translational components of the symmetry operations. That is, by turning screw rotations into rotations, glide reflections into reflections and moving all symmetry elements into the origin. Each crystallographic point group defines the (geometric) crystal class of the crystal.

The point group of a crystal determines, among other things, the directional variation of physical properties that arise from its structure, including optical properties such as birefringency, or electro-optical features such as the Pockels effect.

The point groups are named according to their component symmetries. There are several standard notations used by crystallographers, mineralogists, and physicists.

For the correspondence of the two systems below, see crystal system.

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In Schoenflies notation, point groups are denoted by a letter symbol with a subscript. The symbols used in crystallography mean the following:

• C_n (for cyclic) indicates that the group has an n-fold rotation axis. C_nh is C_n with the addition of a mirror (reflection) plane perpendicular to the axis of rotation. C_nv is C_n with the addition of n mirror planes parallel to the axis of rotation.
• S_2n (for Spiegel, German for mirror) denotes a group with only a 2n-fold rotation-reflection axis.
• D_n (for dihedral, or two-sided) indicates that the group has an n-fold rotation axis plus n twofold axes perpendicular to that axis. D_nh has, in addition, a mirror plane perpendicular to the n-fold axis. D_nd has, in addition to the elements of D_n, mirror planes parallel to the n-fold axis.
• The letter T (for tetrahedron) indicates that the group has the symmetry of a tetrahedron. T_d includes improper rotation operations, T excludes improper rotation operations, and T_h is T with the addition of an inversion.
• The letter O (for octahedron) indicates that the group has the symmetry of an octahedron, with (O_h) or without (O) improper operations (those that change handedness).

Due to the crystallographic restriction theorem, n = 1, 2, 3, 4, or 6 in 2- or 3-dimensional space.

n	1	2	3	4	6
Cn	C1	C2	C3	C4	C6
Cnv	C1v=C1h	C2v	C3v	C4v	C6v
Cnh	C1h	C2h	C3h	C4h	C6h
Dn	D1=C2	D2	D3	D4	D6
Dnh	D1h=C2v	D2h	D3h	D4h	D6h
Dnd	D1d=C2h	D2d	D3d	D4d	D6d
S2n	S2	S4	S6	S8	S12

D_4d and D_6d are actually forbidden because they contain improper rotations with n=8 and 12 respectively. The 27 point groups in the table plus T, T_d, T_h, O and O_h constitute 32 crystallographic point groups.

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An abbreviated form of the Hermann–Mauguin notation commonly used for space groups also serves to describe crystallographic point groups. Group names are

Crystal family	Crystal system	Group names
Cubic		23	mTemplate:Overline		432	Template:Overline3m	mTemplate:Overlinem
Hexagonal	Hexagonal	6	Template:Overline	6⁄m	622	6mm	Template:Overlinem2	6/mmm
	Trigonal	3	Template:Overline		32	3m	Template:Overlinem
Tetragonal		4	Template:Overline	4⁄m	422	4mm	Template:Overline2m	4/mmm
Orthorhombic					222		mm2	mmm
Monoclinic		2		2⁄m		m
Triclinic		1	Template:Overline

Template:Clear

Crystal family	Crystal system	Hermann-Mauguin		Shubnikov[2]	Schoenflies	Orbifold	Coxeter	Order
		(full)	(short)
Triclinic		1	1	${\displaystyle 1}$	C1	11	[ ]+	1
		Template:Overline	Template:Overline	${\displaystyle \tilde{2}}$	Ci = S2	×	[2+,2+]	2
Monoclinic		2	2	${\displaystyle 2}$	C2	22	[2]+	2
		m	m	${\displaystyle m}$	Cs = C1h	*	[ ]	2
		${\displaystyle \frac{2}{m}}$	2/m	${\displaystyle 2:m}$	C2h	2*	[2,2+]	4
Orthorhombic		222	222	${\displaystyle 2:2}$	D2 = V	222	[2,2]+	4
		mm2	mm2	${\displaystyle 2\cdot m}$	C2v	*22	[2]	4
		${\displaystyle \frac{2}{m}\frac{2}{m}\frac{2}{m}}$	mmm	${\displaystyle m\cdot 2:m}$	D2h = Vh	*222	[2,2]	8
Tetragonal		4	4	${\displaystyle 4}$	C4	44	[4]+	4
		Template:Overline	Template:Overline	${\displaystyle \tilde{4}}$	S4	2×	[2+,4+]	4
		${\displaystyle \frac{4}{m}}$	4/m	${\displaystyle 4:m}$	C4h	4*	[2,4+]	8
		422	422	${\displaystyle 4:2}$	D4	422	[4,2]+	8
		4mm	4mm	${\displaystyle 4\cdot m}$	C4v	*44	[4]	8
		Template:Overline2m	Template:Overline2m	${\displaystyle \tilde{4}\cdot m}$	D2d = Vd	2*2	[2+,4]	8
		${\displaystyle \frac{4}{m}\frac{2}{m}\frac{2}{m}}$	4/mmm	${\displaystyle m\cdot 4:m}$	D4h	*422	[4,2]	16
Hexagonal	Trigonal	3	3	${\displaystyle 3}$	C3	33	[3]+	3
		Template:Overline	Template:Overline	${\displaystyle \tilde{6}}$	C3i = S6	3×	[2+,6+]	6
		32	32	${\displaystyle 3:2}$	D3	322	[3,2]+	6
		3m	3m	${\displaystyle 3\cdot m}$	C3v	*33	[3]	6
		Template:Overline${\displaystyle \frac{2}{m}}$	Template:Overlinem	${\displaystyle \tilde{6}\cdot m}$	D3d	2*3	[2+,6]	12
	Hexagonal	6	6	${\displaystyle 6}$	C6	66	[6]+	6
		Template:Overline	Template:Overline	${\displaystyle 3:m}$	C3h	3*	[2,3+]	6
		${\displaystyle \frac{6}{m}}$	6/m	${\displaystyle 6:m}$	C6h	6*	[2,6+]	12
		622	622	${\displaystyle 6:2}$	D6	622	[6,2]+	12
		6mm	6mm	${\displaystyle 6\cdot m}$	C6v	*66	[6]	12
		Template:Overlinem2	Template:Overlinem2	${\displaystyle m\cdot 3:m}$	D3h	*322	[3,2]	12
		${\displaystyle \frac{6}{m}\frac{2}{m}\frac{2}{m}}$	6/mmm	${\displaystyle m\cdot 6:m}$	D6h	*622	[6,2]	24
Cubic		23	23	${\displaystyle 3/2}$	T	332	[3,3]+	12
		${\displaystyle \frac{2}{m}}$Template:Overline	mTemplate:Overline	${\displaystyle \tilde{6}/2}$	Th	3*2	[3+,4]	24
		432	432	${\displaystyle 3/4}$	O	432	[4,3]+	24
		Template:Overline3m	Template:Overline3m	${\displaystyle 3/\tilde{4}}$	Td	*332	[3,3]	24
		${\displaystyle \frac{4}{m}}$Template:Overline${\displaystyle \frac{2}{m}}$	mTemplate:Overlinem	${\displaystyle \tilde{6}/4}$	Oh	*432	[4,3]	48

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Many of the crystallographic point groups share the same internal structure. For example, the point groups Template:Overline, 2, and m contain different geometric symmetry operations, (inversion, rotation, and reflection, respectively) but all share the structure of the cyclic group C₂. All isomorphic groups are of the same order, but not all groups of the same order are isomorphic. The point groups which are isomorphic are shown in the following table:^[3]

Hermann-Mauguin	Schoenflies	Order	Abstract group
1	C1	1	C1	${\displaystyle G_1^1}$
Template:Overline	Ci = S2	2	C2	${\displaystyle G_2^1}$
2	C2	2
m	Cs = C1h	2
3	C3	3	C3	${\displaystyle G_3^1}$
4	C4	4	C4	${\displaystyle G_4^1}$
Template:Overline	S4	4
2/m	C2h	4	D2 = C2 × C2	${\displaystyle G_4^2}$
222	D2 = V	4
mm2	C2v	4
Template:Overline	C3i = S6	6	C6	${\displaystyle G_6^1}$
6	C6	6
Template:Overline	C3h	6
32	D3	6	D3	${\displaystyle G_6^2}$
3m	C3v	6
mmm	D2h = Vh	8	D2 × C2	${\displaystyle G_8^3}$
4/m	C4h	8	C4 × C2	${\displaystyle G_8^2}$
422	D4	8	D4	${\displaystyle G_8^4}$
4mm	C4v	8
Template:Overline2m	D2d = Vd	8
6/m	C6h	12	C6 × C2	${\displaystyle G_{12}^2}$
23	T	12	A4	${\displaystyle G_{12}^5}$
Template:Overlinem	D3d	12	D6	${\displaystyle G_{12}^3}$
622	D6	12
6mm	C6v	12
Template:Overlinem2	D3h	12
4/mmm	D4h	16	D4 × C2	${\displaystyle G_{16}^9}$
6/mmm	D6h	24	D6 × C2	${\displaystyle G_{24}^5}$
mTemplate:Overline	Th	24	A4 × C2	${\displaystyle G_{24}^{10}}$
432	O	24	S4	${\displaystyle G_{24}^7}$
Template:Overline3m	Td	24
mTemplate:Overlinem	Oh	48	S4 × C2	${\displaystyle G_{48}^7}$

This table makes use of cyclic groups (C₁, C₂, C₃, C₄, C₆), dihedral groups (D₂, D₃, D₄, D₆), one of the alternating groups (A₄), and one of the symmetric groups (S₄). Here the symbol " × " indicates a direct product.

1. Leave out the Bravais lattice type.
2. Convert all symmetry elements with translational components into their respective symmetry elements without translation symmetry. (Glide planes are converted into simple mirror planes; screw axes are converted into simple axes of rotation.)
3. Axes of rotation, rotoinversion axes, and mirror planes remain unchanged.

• Molecular symmetry
• Point group
• Space group
• Point groups in three dimensions
• Crystal system

• Point-group symbols in International Tables for Crystallography (2006). Vol. A, ch. 12.1, pp. 818-820
• Names and symbols of the 32 crystal classes in International Tables for Crystallography (2006). Vol. A, ch. 10.1, p. 794
• Pictorial overview of the 32 groups

Template:Crystal systems