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The space group of a
crystal is a mathematical
description of the
symmetry inherent in the
structure. The word 'group' in the
name comes from the
mathematical notion of a group,
which is used to build the set of
space groups.
Space groups in
crystallography
The space groups in three
dimensions are made from
combinations of the 32
crystallographic point groups
with the 14
Bravais lattices which belong
to one of 7
crystal systems. This results
in a space group being some
combination the translational
symmetry of a
unit cell including lattice
centering, and the point group
symmetry operations of reflection,
rotation and rotoinversion (also
called improper rotation).
Furthermore one must consider the
screw axis and glide plane
symmetry operations. These are
called compound symmetry
operatioans and are combinations
of translational and rotation. The
combination of all these symmetry
operations results in a total of
230 space groups describing all
possible crystal symmetries.
Glide planes and screw axes
Two of the symmetry operations
involved in the space groups are
not contained in the corresponding
point group or Bravais lattice.
These are the compound symmetry
operations called the
glide plane and the
screw axis.
A glide plane is a reflection
in a plane, followed by a
translation parallel with that
plane. This is 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 the
fourth of the diagonal of either a
face or space diagonal of the unit
cell. The latter is often called
the diamond glide plane as it
features in the diamond structure.
A screw axis is a rotation
about an axis, followed by a
translation along the direction of
the axis. These are noted by a
number, n, to describe the degree
of rotation, where the number is
how many operations must be
applied to compete a full rotation
(e.g., 3 would mean a rotation one
third of the way around the axis
each time). 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. So, 21 is a
two-fold rotation followed by a
translation of 1/2 of the lattice
vector.
Notation
There are a number of methods
of identifying space groups. The
International Union of
Crystallography publishes a table
(more correctly, a hefty tome of
tables) of all space groups, and
assigns each a unique number.
Other than this numbering scheme
there are two main forms of
notation, the Hermann-Mauguin
notation and Schönflies notation.
The Hermann-Mauguin (or
international) notation is the one
most commonly used in
crystallography, and consists of a
set of four symbols. The first
describes the centering of the
Bravais lattice (P, C, I or
F). The next three describe the
most prominent symmetry operation
visible when projected along one
of the high symmetry directions of
the crystal. These symbols are the
same as used in
point groups, with the
addition of glide planes and screw
axis, described above. By way of
example, the space group of
quartz is P3121,
showing that it exhibits primitive
centering of the motif (i.e. once
per unit cell), with a threefold
screw axis and a two-fold rotation
axis. Note that it does not
explicitly contain the
crystal system, although this
is unique to each space group (in
the case of P3121, it
is trigonal).
Group theory
Mathematically, a space group
is a
symmetry group or symmetry
group type of n-dimensional
structures with
translational symmetry in n
independent directions, such as,
for n = 3, a
crystal. Only discrete
symmetry groups are included in
the categorization; i.e.,
infinitely fine structure or
homogeneity in one or more
directions is excluded.
Two symmetry groups are of the
same crystallographic space
group type if they are the
same up to an
affine transformation of space
that preserves
orientation. Thus e.g. a
change of angle between
translation vectors does not
affect the space group type if it
does not add or remove any
symmetry.
Two symmetry groups are of the
same affine space group type
if they are the same up to an
affine transformation, even if
that inverts orientation.
This can be expressed by saying
that two symmetry groups which are
chiral and each other's
mirror image, are of different
crystallographic space group type,
but of the same affine space group
type.
In 1D and 2D space groups of
the same affine space group type
are also of the same
crystallographic space group type,
but in 3D this need not be the
case: in 2D, the mirror image of a
rotation is a reversed rotation,
which is in the group anyway, and
the mirror image of a mirror is
still a mirror, but the mirror
image of a righthand screw
operation is a lefthand one, not
the inverse of the righthand screw
operation.
The Bieberbach theorem states
that in each dimension all affine
space group types are different
even as abstract groups (as
opposed to e.g.
Frieze groups, of which two
are isomorphic with Z).
The term "space group" is often
used for space group type.
It is often clear from the context
what is meant. However, when
considering subgroup relationships
a specific symmetry group should
not be confused with the space
group type.
Space groups in various
dimensions
In 1D there are two space group
types: those with and without
mirror image symmetry, see
symmetry groups in one dimension.
In 2D there are 17; these 2D
space groups are also called
wallpaper groups or
plane groups.
In 3D there are 230
crystallographic space group
types, which reduces to 219 affine
space group types because of some
types being different from their
mirror image; these are said to
differ by "enantiomorphous
character" (e.g. P3112
and P3212). Usually
"space group" refers to 3D. They
are by themselves purely
mathematical, but play a large
role in
crystallography.
The number of affine space
group types in
n
dimensions is given by sequence
A004029 in
OEIS; the number of
crystallographic space group types
in n
dimensions is given by
A006227.
Grouping space groups by point
group
A symmetry group consists of
isometric
affine transformations; each
is given by an
orthogonal matrix and a
translation vector (which may be
the zero vector). Space groups can
be grouped by the matrices
involved, i.e. ignoring the
translation vectors (see also
Euclidean group). This
corresponds to discrete symmetry
groups with a fixed point: the
point groups. However, not all
point groups are compatible with
translational symmetry; those who
are are called the
crystallographic point groups.
This is expressed in the
crystallographic restriction
theorem. (In spite of these
names, this is a geometric
limitation, not just a physical
one.)
In 1D both space group types
correspond to their own
"crystallographic point group".
In 2D the 17 wallpaper groups
are grouped according to 10
associated crystallographic point
groups: 1-, 2-, 3-, 4-, and 6-fold
rotational symmetry, each with or
without reflections. Thus a
wallpaper group with glide
reflection axes is associated with
the same point group as the
wallpaper group with reflection
axes parallel to these glide
reflection axes.
In 3D this gives a grouping of
the 230 space group types into 32
crystal classes, one for each
associated crystallographic point
group. A space group with a screw
axis is in the same crystal class
as one with a corresponding pure
axis of rotation. Similarly a
space group with a glide plane is
in the same crystal class as one
with a corresponding pure
reflection.
In addition to translations,
and the point operations of
reflection, rotation and improper
rotation, there are combinations
of reflections and rotations with
translation: the
screw axis and the
glide plane.
Screw axis
A rotation of 360°/n
about an axis, combined with a
translation along the axis. A
subscript indicates the
translation distance, as a
multiple of the distance obtained
by dividing that of the
translational symmetry by n.
So, 63 is a rotation of
60° combined with a translation of
1/2 of the lattice vector,
implying that there is also 3-fold
rotational symmetry about this
axis. The possibilities are 21,
31, 41, 42,
61, 62, and
63, and the
enantiomorphous 32, 43,
64, and 65.
Glide plane
A reflection in a plane,
followed by a translation parallel
with that plane. This is 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 the fourth of a diagonal of
a face of the unit cell.
Further categorizing of space
groups
Space groups are categorized by
Bravais lattice and
crystal class. However, for
some combinations there are
multiple space groups, while other
combinations are not possible.
The 230 space group types can
be subdivided in two categories:
- 73 symmorphic space group
types: a space group is
symmorphic if all symmetries can
be described in terms of
rotation axes and reflection
planes all through the same
point (including rotoreflections),
without screw axes and glide
planes). Equivalently, a space
group is symmorphic if it is
equivalent to a
semidirect product of its
point group with its translation
subgroup.
- 157 nonsymmorphic space
group types.
