Symmetry operation

C₁, rotation by 360°, is called the Identity operation and is denoted by E or I. In Identity operation, no change can be observed for the molecule. Even the most asymmetric molecule can undergo identity operation.

A molecule that consists of a plane of symmetry possesses a mirror plane. When this plane of symmetry is parallel to the principal axis of the molecule (molecular z-axis), it is considered as a vertical plane (σ_v). If the plane of symmetry is perpendicular to the principal axis, then it is denoted as a horizontal mirror plane (σ_h). A dihedral mirror plane (σ_d) is the third type of plane of symmetry which bisects the angle between two 2-fold axes perpendicular to the principal axis. Through the reflection of each mirror plane, the molecule must be able to produce an identical image of itself.

The inversion center is a point in space that lies in the geometric center of the molecule. During an inversion operation, all the atoms are moved through the center of the molecule in the opposite direction. As a result, all the cartesian coordinates of the atoms are inverted (i.e. x,y,z to -x,-y,-z).

These are denoted by C_n^m and are rotations of 360°/n, performed m times. The superscript m is omitted if it is equal to one. Here the molecule can be rotated into equivalent positions around an axis.

C_nⁿ, n rotations 360°/n is also an Identity operation. That is a complete set of rotations around the principal axis results in identity.

These are denoted by S_n^m and are rotations of 360°/n followed by reflection in a plane perpendicular to the rotation axis (σ_h). S₁ is usually denoted as σ, a reflection operation about a mirror plane. S₂ is usually denoted as i, an inversion operation about an inversion centre. When n is an even number S_nⁿ = E, but when n is odd S_n²ⁿ = E.

Rotation axes, mirror planes and inversion centres are symmetry elements, not operations. The rotation axis of the highest order is known as the principal rotation axis. It is conventional to set the Cartesian z axis of the molecule to contain the principal rotation axis.

Dichloromethane, CH₂Cl₂. There is a C₂ rotation axis which passes through the carbon atom and the midpoints between the two hydrogen atoms and the two chlorine atoms. Define the z axis as co-linear with the C₂ axis, the xz plane as containing CH₂ and the yz plane as containing CCl₂. A C₂ rotation operation permutes the two hydrogen atoms and the two chlorine atoms. Reflection in the yz plane permutes the hydrogen atoms while reflection in the xz plane permutes the chlorine atoms. The four symmetry operations E, C₂, σ(xz) and σ(yz) form the point group C_2v. Note that if any two operations are carried out in succession the result is the same as if a single operation of the group had been performed.

Methane, CH₄. In addition to the proper rotations of order 2 and 3 there are three mutually perpendicular S₄ axes which pass half-way between the C-H bonds and six mirror planes. Note that S₄² = C₂.