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Point Groups
C1 : no symmetry
Cs : only a plane of symmetry
Ck : only a k rotational axis
Ci : only an inversion center
Ckh : a k rotational axis and σh
Ckv : a k rotational axis and k σv
Dk : only Ck and k C2 rotational axes
Dkh : operations of Dk and σh which implies k σv
Dkd : operations of Dk and k σd which bisect the angles of C2
Sk : only the improper rotation Sk
Td : tetrahedral
Oh : octahedral
H
O
B
N
H
H
O
O
H
H
H
C3h
C3v
Point group representations
A point group representation is a basis set in which the
irreducible representations are the basis vectors. Shown
below is the C2v point group. It has four dimensions.
The dimensions are the symmetry operations. There are
four basis vectors, which are also known as irreducible
representations.
Dkh point groups
N
N
Fe
M
N
N
D2h
D3h
D4h
Dkd point groups
D3d
D5h
D6h
Dkh character table
The D4h point group is a second example. It has 16
dimensions. Note that the symmetry operations are
listed by class. A class refers to a given type of
operation, e.g. reflection, inversion, rotation, etc.
Dkh character table
The D6h point group is a third example. The molecule
benzene belongs to this point group.
High symmetry point groups:
Tetrahedral and octahedral
Tetrahedron (Th)
Octahedron (Oh)
The tetrahedral point group
The Td point group is a high symmetry group. Many
transition metal complexes belong to this group, but also
molecules such as methane, CH4.
Examples of point group assignment
Determining the point group to which a molecule
belongs will be the first step in a treatment of the
molecular orbitals or spectra of a compound.
It is important that this be done systematically. The
flow chart in the figure is offered as an aid, and a few
examples should clarify the process.
Systematic assignment of a
molecule to a point group
Symmetry properties are
used to determine the
molecular orbitals and
spectral features of a
molecule. It is important
to have a systematic
approach to assignment
of the point group.
The scheme gives a
systematic series of
questions that lead to
the point group assignment.
What are the point groups for the following Pt(II) ions?
Cl
Pt
Cl
Cl 2-
Cl
Cl
Pt
Cl
A
Pt
Cl
Br
Cl 2-
Cl
Cl
Pt
Cl
B
Pt
Br
Br
Br 2-
Cl
Pt
Cl
C
Cl
Examples of point group assignment
Cl
Cl
Pt
Pt
Cl
Cl
Cl
Cl
2-
Examples of point group assignment
Cl
Cl
Pt
Pt
Cl
Cl
Cl
Cl
2-
Examples of point group assignment
Cl
Cl
Pt
Pt
Cl
Cl
Cl
Cl
2-
Examples of point group assignment
Cl
Cl
Pt
Pt
Cl
Cl
2-
Cl
Cl
D2h
Examples of point group assignment
Cl
Cl
Pt
Pt
Br
Cl
Cl
Br
2-
Examples of point group assignment
Cl
Cl
Pt
Pt
Br
Cl
Cl
Br
2-
Examples of point group assignment
Cl
Cl
Pt
Pt
Br
Cl
2-
Cl
Br
C2v
Examples of point group assignment
Cl
Cl
Pt
Pt
Br
Br
Cl
Cl
2-
Examples of point group assignment
Cl
Cl
Pt
Pt
Br
Br
Cl
Cl
2-
Examples of point group assignment
Cl
Cl
Pt
Pt
Br
Br
2-
Cl
Cl
C2h
What are the point groups for the following Pt(II) ions?
Cl
Cl Cl 2Cl
Cl Cl 2Cl
Cl Br 2Pt
Cl
Pt
Cl
Pt
Cl
Br
Pt
Cl
Pt
Br
Br
Pt
Cl
Cl
C
B
A
A contains three C2 axes, i.e., [Ck?] is yes with k=2. It contains
a plane of symmetry so [σ?] is yes. The three C2 axes are
perpendicular, i.e, there is a C2 axis and two perpendicular C2's
which means that [⊥C2?] is yes. There is a plane of symmetry
perpendicular to the C2 so [σh?] is yes and we arrive at the D2h
point group.
B contains only one C2 axis, no ⊥C2's, no σh, but it does have
two σv's and is therefore a C2v ion.
C contains a single C2 axis and a horizontal plane (the plane of
the ion) and therefore has C2h symmetry.